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Illustrations on pages 68, 70, and 71 by George Kelvin. Drawings on pages 6, 40, 105, 235, and 264 by Sidney Harris. Library of Congress Cataloging-in-Publication Data Pauling, Linus, 1901How to live longer and feel better. Bibliography: p. Includes index. 1. Nutrition. 2. Vitamins in human nutrition. 3. Orthomolecular therapy. 4. Health. I. Title. RA774.P38 1986 613.2 85-25321 ISBN 0-7167-1781-6 ISBN 0-7167-1775-1 (pbk.) Copyright © 1986 by W. H. Freeman and Company No part of this book may be reproduced by any mechanical, photographic, electronic process, or in the form of a phonographic recording, nor may it be stored in a retrieval system, transmitted, or otherwise copied for public or private use, without written permission from the publisher. Printed in the United States of America 1234567890 H 4321089876
C o n te n ts
Introduction ix I THE REGIMEN / 1 Good Nutrition for a Good Life 3 2 A Regimen for Better Health 8 3 The Old Nutrition and the New 77 4 Proteins, Fats, Carbohydrates, and Water 25 5 Foods as the Source of Heat and Energy 32 6 Two Eating Problems 36 II THE NEW NUTRITION 45 7 How Vitamins Were Discovered 47 8 Vitamins and Evolution 55 9 Vitamins in the Body 64 10 Biochemical Individuality 81
III O R T H O M O L E C U L A R M E D IC IN E 91 11 Orthomolecular M edicine Defined 93 12 The Immune System 100 13 The Common Cold 107 14 Influenza and Other Infectious Diseases 123 15 Wounds and Their Healing 136 16 M uscular Activity 141 17 The H eart 145 18 Cardiovascular Disease 153 19 Cancer 163 20 The Brain 181 21 The Allergies 196 22 Arthritis and Rheumatism 202 23 The Eye, the Ear, and the M outh 207 24 Aging: Its M oderation and Delay 212 IV V ITA M IN S A N D D RU G S 223 25 Organized M edicine and the Vitamins 225 26 Vitamins and Drugs Compared 237 27 The Low Toxicity of Vitamins 249 28 The Side Effects of Vitamins 257 V H O W T O LIV E L O N G E R A N D F E E L B E T T E R 269 29 A H appy Life and a Better World 271 Bibliography 275 About the Author 307 Index 313
I n tr o d u c tio n
This book discusses some simple and inexpensive measures that you can take to lead a better and longer life, with greater enjoyment and fewer illnesses. The most important recommendation is that some vitamins be taken every day to supplement the vitamins that you get in your food. The best amounts of the supplementary vitamins and the best way to take them are discussed in the first chapters of the book, and the reasons for taking them are discussed in the following chapters. I am a scientist, a chemist, physicist, crystallographer, molecular biolo gist, and medical researcher. Twenty years ago I became interested in the vitamins. I discovered that the science of nutrition had stopped developing. The old professors of nutrition who had helped to develop this science fifty years ago seemed to be so well satisfied with their accomplishment that they ignored the new discoveries that were being made in biochemistry, molecu lar biology, and medicine, including vitamins and other nutrients. Although a new science of nutrition was being developed, these old professors of nutrition continued to teach their students the old ideas, many of them wrong, such as that no person in ordinary health needs to take supplemen tary vitamins and that all that you need to do for good nutrition is to eat some of each of the “four foods” each day.
As a result of this poor teaching, many nutritionists and dieticians today still practice the old nutrition, with the result that the American people are not as healthy as they should be. Physicians also contribute to this problem. Most of them have received only a small amount of instruction in nutrition (most of it, of course, out of date) in medical school, and since then have been kept so busy in their care of their patients as not to have time to follow the new developments about vitamins and other nutrients. When I discovered that the new developments in the field of nutrition were being ignored I became so interested that for twenty years most of my effort has been devoted to research and education in this field. I have been fortunate in this work to have had and to continue to have the collaboration of many able scientific and medical investigators in Stanford University and Linus Pauling Institute of Science and Medicine. Fifteen years ago many people were already convinced, on the basis of their own experience, that an increased intake of vitamin C provides some protection against the common cold, even though most physicians and au thorities in the field of nutrition continued to describe vitamin G as having no value in controlling the common cold or any other disease except its specific deficiency disease, scurvy. When I examined the medical literature I found that a number of excellent studies had been carried out, and that most of them showed that vitamin C does have value in controlling the common cold. My concern about the failure of the medical authorities to pay the deserved attention to the existing evidence caused me to write my book Vitamin C and the Common Cold. When this book was published it received favorable comment from some reviewers, but was quite strongly criticized by others. The discussion that followed stimulated a number of investigators, including Professor George Beaton, head of the Department of Nutrition in the School of Hygiene of the University of Toronto, to begin controlled trials. These trials all sup ported the conclusion that vitamin C has value in controlling the common cold. As a result, the medical and nutritional authorities no longer claim that vitamin G has no value in connection with the common cold, although they may contend that the amount of protection provided by it is not great enough to justify the bother and expense of taking the vitamin. In the course of my continued studies of vitamin G I learned that this vitamin exerts a general antiviral action and provides some protection not only against the common cold but also against other viral diseases, includ ing influenza, mononucleosis, hepatitis, and herpes. The common cold is a nuisance, but is not very dangerous. Only rarely does it lead to complica tions that cause death. Influenza (the flu), on the other hand, is a very serious and dangerous disease. In the great influenza pandemic of
1918-1919 the disease was contracted by about 85 percent of the popula tion in all countries and killed about 1 percent, including many healthy young adults—the estimated total number of deaths being about 20 million. An outbreak of influenza in early 1976 with a virus similar to that of the 1918-1919 pandemic also caused great concern. It is important to know that a good intake of vitamin C can improve your general health in such a way as to provide significant protection against these diseases. In addition, good intakes of vitamin C and other vitamins can improve your general health in such a way as to increase your enjoyment of life and can help in controlling heart disease, cancer, and other diseases and in slowing down the process of aging. All of these questions are discussed in this book. I hope that the book will help many people to avoid serious illness and will enable them to lead and to enjoy healthier and longer lives. I thank Mrs. Dorothy Munro, Mrs. Corrine Gorham, Mrs. Ruth Reyn olds, Dr. Ewan Cameron, Dr. Zelek Herman, Dr. Linus Pauling, Jr., Dr. Crellin Pauling, Dr. Kay Pauling, Dr. Armand Hammer, Mr. Ryoichi Sasakawa, and Dr. Emile Zuckerkandl for their help. I am grateful to Dr. Abram Hoffer, Dr. Humphry Osmond, and Dr. Irwin Stone for having aroused my interest in vitamins about twenty years ago, and to Linda Chaput and her associates in W. H. Freeman and Company for their help in the publication of this book. I am especially grateful to my friend Gerard Piel for his continued encouragement and his contributions to the book. Linus Pauling Linus Pauling Institute of Science and Medicine 440 Page Mill Road Palo Alto, California 94306 September 1, 1985
1.G o o d
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I believe that you can, by taking some simple and inexpensive measures, lead a longer life and extend your years of well-being. My most important recommendation is that you take vitamins every day in optimum amounts to supplement the vitamins that you receive in your food. Those optimum amounts are much larger than the minimum supplemental intake usually recommended by physicians and old-fashioned nutritionists. The intake of vitamin G they advise, for example, is not much larger than that necessary to prevent the dietary-deficiency disease scurvy. My advice that you take larger amounts of G and other vitamins is predicated upon new and better understanding of the role of these nutrients—they are not drugs—in the chemical reactions of life. The usefulness of the larger supplemental intakes indicated by this understanding has been invariably confirmed by such clinical trials as have been run and by the first pioneering studies in the new epidemiology of health. By the proper intakes of vitamins and other nutrients and by following a few other healthful practices from youth or middle age on, you can, I believe, extend your life and years of well-being by twenty-five or even thirty-five years. A benefit of increasing the length of the period of well being is that the fraction of one’s life during which one is happy becomes greater. Youth is a time of unhappiness; young people, striving to find their
places in the world, live under great stress. The deterioration in health as the result of age usually makes the period before death a time of unhappi ness again. There is evidence that there is less unhappiness associated with death at an advanced age than at an early age. For such reasons it is sensible to take the health measures that will increase the length of the period of well-being and the life span. If you are already old when you begin taking vitamin supplements in the proper amounts and following other practices that improve your health, you can expect the control of the process of aging to be less, but it may still amount to fifteen or twenty years. For most of the statements in the following chapters I give reference to the published reports of the observations on which the statements are based. It is not possible, however, for me to substantiate in the same way the foregoing statements of my beliefs about the increase in the length of the period of well-being and the length of life. I have formed these beliefs on the basis of my knowledge of a great many observations about the effects of vitamins in varying amounts on animals and human beings under various conditions of good or poor health, including some significant epidemiologi cal studies. There is, however, no single study to which I can point as showing with high statistical significance that the amount of benefit is as great as I believe it to be. One complication, discussed in a later chapter, is that human beings differ from one another; they show a pronounced bio chemical individuality. It is far easier to obtain reliable information about the factors determining the health of guinea pigs or monkeys than of hu man beings, and I have relied to some extent on the studies made on these and other animal species. I am, for example, impressed by the fact that the Committee on the Feeding of Laboratory Animals of the U.S. National Academy of Sciences-National Research Council recommends far more vitamin C for monkeys than the Food and Nutrition Board of the same U.S. National Academy of Sciences-National Research Council recommends for human beings. I am sure that the first committee has worked hard to find the optimum intake for the monkeys, the amount that puts them in the best of health. The second committee has not made any effort to find the optimum intake of vitamin C or of any other vitamin for the American people. In its Recommended Daily Allowances, so well publicized that they are referred to on breakfast-cereal boxes by the initials RDA, the committee rations the vitamins at not much above the minimum daily intake required to prevent the particular deficiency disease that is associated with each of them. No evidence compels the conclusion that the minimum required intake of any vitamin comes close to the optimum intake that sustains good health. The best supplementary amounts of the vitamins and the best way to take
them I discuss in the first chapters of this book, and the reasons for taking them in the chapters that follow. As you will see, I think that vitamin C is the most important in the sense that the value of increasing the intake of this vitamin beyond that supplied by an ordinary diet is greater than for the other vitamins, but the other vitamins are also important. When it comes to concern about health, an important question is the extent to which a person in the United States should depend on his or her physician. At the present time the main job of the physician is to try to cure the patient when he or she appears in the office with a specific illness. The physician usually does not make any great effort to prevent the illness or to strive to put the person consulting him or her in the best of health. A remarkable book has been published recently (1984) by Dr. Eugene D. Robin, professor of medicine and physiology in Stanford Medical School. Its title is Matters of Life and Death: Risks vs. Benefits of Medical Care. In it the author discusses the drawbacks of present-day medicine as well as its strengths. His thesis is that there are “serious flaws in the basic processes by which diagnostic and therapeutic measures are introduced and used in medicine” and that “potential or actual patients can reduce the risks and increase the benefits of their medical care if they are familiar with the flaws in medicine.” Robin writes that if you pay attention to your own health and do not see the “doctor as God,” you can avoid serious errors in your own care. “You will be advised,” he says, “to consult doctors only when you believe that you are truly ill. By restricting your medical encoun ters to those that are absolutely necessary you will be avoiding the risks inherent in most diagnostic and therapeutic procedures.” “This advice,” Robin says, “tends to slight an important function that doctors have assumed in our society: dealing with patients whose main problem is an unhappy life. It is your privilege to consult a doctor for that purpose, but you should know that few doctors have high cure rates for unhappy lives, so that the chances of obtaining real help are small. More over, your visit may start a series of potentially dangerous medical tests and treatments. If, as a result of reading this book, you see that even a decision to consult a doctor is a serious and potentially risky one, that it requires some estimate of potential risks as well as potential benefits, you will have spent your time well. “You will be cautioned to avoid hospitalization unless you are seriously ill and only a hospital has the facilities for your treatment. Many hospital izations are unnecessary. Hospitals can be dangerous places.” Robin does not discuss vitamins in his book. This omission is probably the result of his having no more knowledge about vitamins that most other physicians have. If he knew more about vitamins, he might have warned his readers to be careful about accepting their doctor’s advice about vitamins
and other aspects of nutrition, because most physicians and surgeons re ceived little instruction in this field in medical school and have picked up much misinformation since their graduation. It is particularly important that you not let your doctor stop your vitamin supplements when you are hospitalized. That is when you have the greatest need for them. In April 1970, I wrote to Dr. Albert Szent-Gyorgyi, the man who first separated ascorbic acid, which is another name for vitamin C, from the plant and animal tissues in which it occurs. I asked his opinion about vitamin C, especially with relation to the optimum rate of intake. He gave
me permission to quote part of his answering letter, as follows. “As to ascorbic acid, right from the beginning I felt that the medical profession misled the public. If you don’t take ascorbic acid with your food you get scurvy, so the medical profession said that if you don’t get scurvy you are all right. I think that this is a very grave error. Scurvy is not the first sign of the deficiency but a premortal syndrome, and for full health you need much more, very much more. I am taking, myself, about 1 g a day. This does not mean that this is really the optimum dose because we do not know what full health really means and how much ascorbic acid you need for it. What I can tell you is that one can take any amount of ascorbic acid without the least danger.” The medical profession and the powerful medical institutions and enter prises in this country have taken to calling themselves the health profession, health centers, and health companies. This is a misnomer for what is really the sickness industry. I like the definition of health set out in the constitu tion of the World Health Organization, which states “Health is a state of complete physical, mental, and social well-being and not merely the ab sence of disease and infirmity.” The World Health Organization constitution goes on to say “The enjoy ment of the highest attainable standard of health is one of the fundamental rights of every human being without regard to race, religion, political belief and economic or social condition.” This is a right that only a minority of the world population can yet enjoy. It is a right open to the lucky people of this country who have the material wealth to make it real. It is a right that is open to you. All that you need to do is to assert it by sensible behavior. What is more, thanks to the new science of nutrition, you can today multi ply the benefits of healthy habits by taking, every day, the optimum amounts of the essential vitamins. No one knows the state of health of a person better than the person himself or herself. It is important to think about one’s health and to act in such a way as to improve it.
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The measures that you take to improve your health and prolong your life should not be so burdensome and disagreeable as to interfere seriously with the quality of your life and make it difficult for you to continue with the regimen day after day, year after year. Compliance is very important. The regimen described in the following paragraphs is of such a nature that you should be able to adhere to it rigorously, day after day, for the rest of your life. The regimen does not include every health measure of which I have knowledge. Moreover, it does not take into account the special nutritional needs of individuals. For example, persons with a tendency toward arthritis might benefit by increases in vitamin C, niacinamide, and vitamin B6. The regimen is instead an average or basic one, which should benefit nearly every person in the United States. Additional benefits may result from changes made in response to biochemical individuality. The steps of the regimen are as follows: 1. Take vitamin C every day, 6 grams (g) to 18 g (6000 to 18,000 milli grams [mg]), or more. Do not miss a single day. 2. Take vitamin E every day, 400 IU, 800 IU, or 1600 IU.* *IU stands for International Unit, the quantity of a vitamin (or other substance) specified in accordance with an international convention adopted by the World Health Organization.
3. Take one or two Super-B tablets every day, to provide good amounts of the B vitamins. 4. Take a 25,000 IU vitamin A tablet every day. 5. Take a mineral supplement every day, such as one tablet of the Bronson vitamin-mineral formula, which provides 100 mg of calcium, 18 mg of iron, 0.15 mg of iodine, 1 mg of copper, 25 mg of magne sium, 3 mg of manganese, 15 mg of zinc, 0.015 mg of molybdenum, 0.015 mg of chromium, and 0.015 mg of selenium. 6. Keep your intake of ordinary sugar (sucrose, raw sugar, brown sugar, honey) to 50 pounds per year, which is half the present U.S. average. Do not add sugar to tea or coffee. Do not eat high-sugar foods. Avoid sweet desserts. Do not drink soft drinks. 7. Except for avoiding sugar, eat what you like—but not too much of any one food. Eggs and meat are good foods. Also, you should eat some vegetables and fruits. Do not eat so much food as to become obese. 8. Drink plenty of water every day. 9. Keep active; take some exercise. Do not at any time exert yourself physically to an extent far beyond what you are accustomed to. 10. Drink alcoholic beverages only in moderation. 11. DO NOT SMOKE CIGARETTES. 12. Avoid stress. Work at a job that you like. Be happy with your family. The main feature of this regimen is the vitamin supplements. Taking them need not be burdensome. It is easy to get in the habit of taking your vitamins every day, and it is important to do so. The great advantage of this regimen over other proposed methods of prolonging life and improving health is that it is firmly based on the new science of nutrition that has been developed only during recent years. The greatest difference between this new science and the old nutrition is the recognition that vitamins taken in the optimum amounts have far greater value than when taken in the usually recommended small amounts, shown in the illustration on page 10. Moreover, with the optimum intake of sup plementary vitamins there is no longer so much need to stress other dietary measures, such as decreasing the intake of animal fat and not eating eggs. The regimen that I recommend permits compliance, day after day, year after year. A burdensome or disagreeable regimen will not be followed by many people. The quality of life is enhanced when one is liberated from these dietary restrictions.
Recommended daily allowances (RDA) These allowances, set by the Food and Nutrition Board of the U.S. National Academy of Sciences-National Research Council, specify for adult males the amounts of thirty-three nutrients needed for preventing overt manifestation of deficiency disease in most persons. The list includes four macronutrients— water, carbohydrates, fats, and protein—and twenty-nine micronutrients to be taken daily in food and supplements. The RDA for vitamins typically fall short of the optimum intakes required for the best of health. Other nutrients, probably or possibly required, not shown here, are the essential fatty acids, para-aminobenzoic acid (PABA), choline, vitamin D, vitamin K, selenium, chromium, manganese, cobalt, nickel, zinc, molybdenum, vanadium, tin, and silicon.
The discovery of vitamins three quarters of a century ago and the recog nition that they are essential elements of a healthy diet was one of the most important contributions to health ever made. Of equal importance was the recognition about twenty years ago that the optimum intakes of several of the vitamins, far larger than the usually recommended intakes, lead to further improvement in health, greater protection against many diseases, and great value as an adjunct to the appropriate conventional therapy in the treatment of diseases. The principal way in which vitamin C and other vitamins function is by strengthening the natural protective mechanisms of the human body, especially the immune system, and by increasing the effectiveness of enzymes in catalyzing biochemical reactions. The optimum daily amounts of vitamins are far larger than the amounts that can be obtained in food, even by selecting foods for their high vitamin content. The only way to obtain the amounts of vitamins that put you in the best of health is to take vitamin supplements. For example, to obtain the 18,000 mg of vitamin C that I take each day I would have to drink more than 200 large glasses of orange juice. To secure my recommended intakes of supplementary vitamins and min erals, shown in the table below, I take only four tablets a day. These are one 800-IU vitamin E capsule, one Super-B tablet, one vitamin and min eral tablet, and one 25,000-IU vitamin A capsule. I take them in the evening. I take much of my vitamin C in the morning, before breakfast, 12 g (three level teaspoonfuls) of pure crystalline ascorbic acid either dis solved in orange juice to buffer it or in water with a small amount of baking soda (sodium hydrogen carbonate) added to make an effervescent drink. Recommended daily adult intakes of vitamins RDA
Williams
Allen*
Leibovitz1
This book
Vitamin G 60 mg 2500 mg 1500 mg 2500 mg 1000-18,000 mg Vitamin E 400 IU 600 IU 300 IU 10 IU 800 IU Vitamin A 5000 IU 15,000 IU 15,000 IU 20,000 IU 20,000-40,000 IU Vitamin K 100 mg none none none none Vitamin D 400 IU 300 IU 800 IU 400 IU 800 IU 20 mg 300 mg Thiamine, B, 1.5 mg 100 mg 50-100 mg Riboflavin, B2 1.7 mg 20 mg 200 mg 100 mg 50-100 mg 750 mg 300 mg Niacinamide, B3 18 mg 200 mg 300-600 mg 2.2 mg 30 mg 350 mg 100 mg Pyridoxine, B6 50-100 mg 90 mg 1000 mg Cobalamin, B12 100 mg 100-200 mg 3 mg Folacin 400 mg 400 mg 400 mg 400 mg 400-800 mg Pantothenic acid 150 mg 500 mg 200 mg none 100-200 mg "Harrell et al., 1981. Teibovitz, 1984.
Vitamin C may also be taken as sodium ascorbate or calcium ascorbate. If I feel tired later in the day or feel that I have been exposed to a cold virus, I take a few 1-g tablets or another spoonful of ascorbic acid. At this writing, in the year 1985, the four tablets I take every day plus the 18 g of vitamin C (L-ascorbic acid, fine crystals) cost me by mail order, postage paid, (from Bronson Pharmaceuticals, 4526 Rinetti Lane, La Canada, Calif. 91011) the total sum of 41 cents a day. If I were to take, instead, the six tablets of the Roger J. Williams Fortified Insurance Formula, offered in the Bronson catalog, containing somewhat smaller amounts of these nutrients plus some others, the cost would be 37 cents a day. Thus these vitamin-mineral supplements, which can mean the differ ence for you between ordinary poor health and really good health, need cost you only as much as one small chocolate bar. Even if, as a cancer patient, you were to take 50 g of vitamin C per day, it would cost only 78 cents, and with the other vitamins and minerals only $1.00 altogether, a negligible cost in comparison with the other expenses for a patient’s care. The values of the RDA given in the table on page 11 are those for adult males from the 1980 edition of the Recommended Dietary Allowances; the values for women and children are somewhat different. The Williams values are for the Fortified Insurance Formula of Professor Roger J. Williams; the Williams tablets also contain para-aminobezoic acid, biotin, choline, inositol, rutin, and eleven minerals (calcium, magnesium, phospho rus, iron, zinc, copper, manganese, chromium, molybdenum, iodine, and selenium). The Allen formula also contains eight minerals. Brian Leibovitz (in his book Carnitine) also recommends biotin, choline, inositol, bioflavo noids, and ten minerals. The essential minerals differ from the vitamins in that overdoses of min erals may be harmful. Do not increase your vitamin intake by taking a large number of vitamin-mineral tablets. Limit your mineral intake to the recommended amounts. It is important not to stop the vitamin supplements, even for a single day. We know that there is a rebound effect on stopping the intake of vitamin C, such as to increase temporarily the risk of disease (Chapters 13 and 19). There may be similar rebound effects also for the other water-soluble vita mins, although none has been reported. In general, the sensible way to buy vitamins is to check the prices and to buy the cheapest. It is required by the Food and Drug Administration (FDA) that the contents be stated on the label. There are probably a few unscrupulous companies, but usually the label can be relied on. The range of prices for essentially the same items is far larger for vita mins than for most consumer goods, such as beefsteak or a television set.
When I began checking the prices of vitamins fifteen years ago, I found that one company was selling a solution of vitamin C said to be specially pre pared for old people at one thousand times the price of ordinary vitamin G, and another company was selling vitamin G tablets at one hundred times the ordinary price. I no longer find such tremendous overpricing, but if you do not check you might pay five times or even ten times the proper amount. The catalog of a reliable company can be used as a reference standard, or you may check the advertisements in Prevention magazine. It is wise not to buy vitamins from a salesman and not to buy from a company that does not have a price list that would permit you to compare prices. Sometimes the effort is made to charge a higher price by using names that have little significance, such as Rose Hips Vitamin G (ordinary vita min G with a little rose-hip powder added), chelated vitamins and miner als, “natural” vitamins, etc. Also, brands prescribed by a physician may cost four times as much as the proper price. Most vitamin preparations are stable. Ascorbic acid in the form of fine crystals or crystalline powder kept in a brown or opaque white bottle is stable indefinitely and can be kept for years. Dry tablets are also reason ably stable and can be kept for years in a brown or opaque white bottle. Solutions of ascorbic acid may be oxidized when exposed to air and light. A solution of ascorbic acid in water may, however, be kept for several days in a refrigerator without significant oxidation. You may have to use some care not to be taken in by unscrupulous companies. After I had recommended pure vitamin-C crystals or powder in my book Vitamin C and the Common Cold I saw an advertisement for “Vitamin C Powder” at a price just under $10 per kilogram (kg). I bought a bottle from the company, which was based in Kansas City, Missouri, and found in small print on the label the statement, “Each level tablespoonful contains 500 mg of ascorbic acid.” A level tablespoonful is about 14 g. Accordingly the preparation contains only 36 g of ascorbic acid in 1000 g of powder; only one twenty-eighth of the powder is ascorbic acid, and the price is $280 per kilogram of vitamin G, not $10. I wrote to the FDA about this misrepresentation and received in reply a statement that the FDA could do nothing about the matter. I then wrote to the Federal Trade Commission, which issued a cease-and-desist order on the company. The most important part of my recommended regimen is to take the optimum amounts of the vitamins every day. This need not, as I have shown, involve swallowing more than a half-dozen tablets a day. My main other recommendation about diet (see Chapter 6) is to decrease your intake of sucrose (ordinary sugar, including raw sugar, brown sugar, syrup, and honey). You can improve your health significantly by reducing your sugar
intake to half the U.S. average of 100 pounds per year, and you can do it by never putting sugar in tea or coffee, avoiding soft drinks, and eating sweet desserts and candy only rarely. As to your diet otherwise, I think that you should for the most part eat what you like, rather than try to follow a restrictive diet that you have trouble conforming to and that does not add to your pleasure in life. Eat the foods that you like (except the high-sugar foods), but do not eat such large amounts as to make you overweight. It is a good idea not to eat large amounts of meat. One quarter of a pound of meat provides 25 g of protein, about half the recommended amount per day. If your high intake of vitamin G keeps your serum choles terol below 200 mg per deciliter (dl), there is no need for you to take special care to eliminate animal fat from your diet or to avoid drinking milk and eating eggs, both of which are good foods. About 10 percent of adult Europeans and most Asians and Africans have digestive problems when they drink milk. At the end of infancy they stop making lactase, which is an enzyme involved in digesting milk sugar (lac tose). Milk is a good food, especially as a source of calcium (about 500 mg per pint). The lactase-deficient person can, however, eat cheese, which is also high in calcium. Even though a major reason for eating fruits and vegetables is to obtain vitamins, and this need may be satisfied by taking vitamin supplements, it is a good idea to include fruits and vegetables in the diet. A moderate amount of regular exercise is good; also sleeping seven or eight hours a night, avoiding stressful situations, having an occupation that you like, and in general, enjoying life. It is wise not to rely entirely upon dietary supplements for other essential nutrients, although they can be obtained as such in tablet and in other forms. “Essential” in this usage designates substances not manufactured in the body: certain amino acids and fats and many of the vitamins. The essential amino acids are not required as a dietary supplement if an ade quate supply of protein is ingested. Moreover, although it is believed that the most important essential nutrients for humans are known, there is still the possibility that some have remained undiscovered. For this reason I agree with the first recommendation of the specialists in nutrition that everyone should eat a balanced diet, with a good amount of green vegeta bles, well prepared, and fresh fruits, such as oranges and grapefruit. Since human beings show biochemical individuality, there is the possibil ity that a person may respond in an unusual way to an increased intake of vitamin C. Because vitamin G is required as an essential nutrient, and all of our ancestors tolerated it for millions of years, it is very unlikely that anyone would have a serious allergic response to it. There is, however, a
slight possibility of allergy to the filler, if tablets are taken in preference to the powder, which is pure crystalline ascorbic acid. It is, of course, wise to increase or decrease the daily intake of this nutrient gradually. A few months of experience should be enough to tell you whether the amount of ascorbic acid that you are ingesting approximates the desirable amount, the amount that provides protection against the common cold. That amount in the nutrition of older people can also reduce the misery of arthritis and carpal tunnel syndrome and many other ailments. If you take 1 g per day and find that you have developed two or three colds during the winter season, it would be wise to try taking a larger daily quantity. Also, if you are exposed to a cold, by having been in contact with a person suffering from a cold, or if you have become chilled by exposure or tired by overwork or lack of sleep, it would be wise to increase the amount of vitamin C ingested. It is wise to carry some 1000-mg tablets of ascorbic acid with you at all times. At the first sign that a cold is developing, the first feeling of scratchi ness of the throat, presence of mucus in the nose, or muscle pain or general malaise, begin the treatment by swallowing two or more 1000-mg tablets. Continue the treatment for several hours by taking an additional two tab lets or more every hour. If the symptoms disappear quickly after the first or second dose of ascor bic acid, you may feel safe returning to your usual regimen. If, however, the symptoms continue, the regimen should be continued, with the inges tion of 10 g to 20 g of ascorbic acid per day. The physician Edme Regnier has pointed out (1968) that his observations indicate that when a cold is suppressed or averted by the use of an adequate amount of vitamin C the viral infection does not disappear at once but remains suppressed, and that it is accordingly important that the vitamin-C regimen be continued for an adequate period of time. It may be worthwhile to help control a cold by the topical application of a solution of sodium ascorbate, made by dissolving 3.1 g of sodium ascor bate in 100 milliliters (ml) of water. Braenden (1973), who has reported success in curing most colds or markedly alleviating the symptoms by this method, recommends introducing twenty drops of this solution into each nostril with an eye dropper. He has pointed out that in this way a local concentration of ascorbate a thousand times the value produced by oral administration can be reached. Ascorbic acid is inexpensive and harmless, even when it is ingested in large amounts. A common cold, when it develops, may involve serious dis comfort and suffering, inconvenience, reduced efficiency, and even disabil ity for some days. Moreover, it may lead to the complications of more serious infections. It is accordingly better to overestimate the amount of
ascorbic acid needed to control the cold than to underestimate it. It may be desirable to increase the intake to the bowel tolerance limit, as discussed in Chapter 14. You must remember, too, to be on the lookout for the first symptoms of the cold and to be prepared to take immediate action. If you wait a day, or even a few hours, and if you take too small an amount of the vitamin, the cold may reach the stage where it cannot be stopped. It is fortunate that vitamins are so cheap that even the high-potency supplements can be afforded by nearly every person in this country. My own rather large intake costs less than a can of soft drink, such as root beer, each day. You should develop a simple regimen about your supplementary vita mins, such that you do not forget to take them. Also, you should develop good habits about moderate exercise, eating healthful foods that appeal to you, avoiding sucrose, not smoking, drinking large amounts of water, and drinking alcoholic liquors only in moderation, in such a way as not to be a burden to you but rather a pleasure, so that you have no trouble in continu ing the regimen. The goal is to lead a good and satisfying life, free to as great an extent as possible from the suffering caused by poor health. As the value of the optimum intakes of supplementary vitamins becomes known, it may well be recognized that the last period of the twentieth century, as well as the first period, has involved discoveries about vitamins that have not only already led to great improvement in human health and well-being but also can lead to even greater improvement in the future.
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T h e w o r l d o f t o d a y is d i f f e r e n t f r o m t h a t o f o n e h u n d r e d y e a r s a g o . W e n o w h a v e a m u c h g re a te r u n d e rs ta n d in g o f n a tu re th a n o u r g ra n d p a re n ts h a d . W e h a v e e n te r e d th e a to m ic a g e , th e e le c tro n ic a g e , th e n u c le a r a g e , th e a g e o f j e t p la n e s , te le v is io n , a n d m o d e r n m e d ic in e a n d its w o n d e r d r u g s . F o r t h e g o o d o f o u r h e a l t h , w e s h o u l d a l s o r e c o g n i z e t h a t t h i s is t h e a g e o f v ita m in s .
The world has been changed by the discoveries made by scientists. Some times the changes have occurred rapidly. For example, the fission of the nuclei of uranium atoms was discovered in 1938; and by 1945, after a crash program, nuclear bombs had been devised, constructed, and used in war. Insulin was discovered by Sir F. G. Banting, C. H. Best, J. J. R. McLeod, and J. B. Collip in 1922, and within a couple of years thousands of diabetic patients were being kept alive and in reasonably good health by injection of this hormone. Sometimes, however, there is a surprising delay. One of the best known examples is penicillin. This important substance was discov ered in 1929 by Alexander Fleming, who showed that it exerted antibacte rial action, but it began to be used therapeutically only in 1941, by W. H. Florey and E. B. Chain. An older example is the delay in accepting the idea that childbed fever could be prevented by having the doctor wash his hands after delivering one
infant before going to the next one. The American writer and physician Oliver Wendell Holmes in 1843 published an article on the contagiousness of this disease. It brought him bitter personal abuse. In 1847 the Hungar ian physician Ignaz Philipp Semmelweiss recommended that physicians wash their hands in chlorinated water between deliveries. In his clinic in Vienna and then in Budapest he himself was able to reduce the puerperal mortality rate from the terrible value of 16 percent to 1 percent. Reaction ary physicians nonetheless rejected his ideas for years. He became embit tered and insane before he died in 1865. The discovery of vitamins during the first third of the twentieth century and the recognition that they are essential elements of a healthy diet was one of the most important contributions to health ever made. Of equal importance was the recognition, about twenty years ago, that the optimum intakes of several of the vitamins, far larger than the usually recommended intakes, lead to further improvement in health, greater protection against many diseases, and enhanced effectiveness in the therapy of diseases. The potency of vitamin G and other vitamins is explained by the new under standing that they function principally by strengthening the natural protec tive mechanisms of the body, especially the immune system. The nutritional establishment has shown itself to be, however, as sluggish in recognizing this discovery as the medical establishment was in its response to Holmes and Semmelweiss. As early as 1937 Albert Szent-Gyorgyi, the scientist who isolated vitamin G, had said that vitamins, used in the proper way, could have fantastic results in improving human health. Yet even now, a half century later, the old-fashioned nutritionists, speaking with the authority of the Food and Nutrition Board of the U.S. National Academy of Sciences-National Re search Council, continue to ignore the evidence about the value of the optimum intakes of these important substances. They persist in recom mending no more than the minimum supplementary intakes, established by clinical experience a half century and more ago, necessary to prevent the diseases associated with deficiency of the vitamins in the diet. Their recom mendations stand in the way of wider popular understanding and practice of the new nutrition. The optimum intakes of the vitamins shown in the table in Chapter 2 and urged in this book are also based upon evidence from clinical trials and experience. That evidence is illuminated by understanding gained through the powerful new methods of molecular biology; we know and are learning to know better just what role each vitamin molecule plays in the chemistry of the body. Thus, by the classic interaction of clinic and laboratory, molec ular biology explains what the clinic finds, and the clinic confirms the optimum intakes commended by molecular biology.
My interest in the question of the nature of life and the structure of the characteristic molecules in the human body and other living organisms began in 1929. That was when Thomas Hunt Morgan and most of the younger men who had collaborated with him in locating Mendel’s gene, the basis of heredity, in the chromosomes in the nucleus of the cell came from Columbia University to the California Institute of Technology to organize the new Division of Biological Sciences. I had been trained in physics and chemistry. With my interest now drawn to genetics, I formulated a theory of the phenomenon of crossing-over of chromosomes, which I presented at a biology symposium but did not publish in a scientific journal. Then in 1935 I began, with my students and other collaborators, to study the structure and properties of hemoglobin and other proteins, the structure of antibodies and the nature of immunological reactions, and the abnormal structures of protein molecules that show up in sickle-cell anemia and other molecular diseases. In 1963 I decided to investigate the molecular basis of mental disease. During the next ten years my associates and I, with the support of grants from the Ford Foundation and the National Institute of Mental Health, carried out studies of the biochemistry and molecular basis of mental retar dation and schizophrenia, as well as of the phenomenon of general anesthe sia (Pauling, 1961). It was this work that led me to become interested in vitamins. In 1964 I read the reports of two psychiatrists, Dr. Humphry Osmond and Dr. Abram Hoffer, who were working in Saskatoon, Saskatchewan, Canada. I read with astonishment that they were giving as much as 50 grams per day of a vitamin (B3, either niacin or niacinamide) to some patients with acute schizophrenia. I knew that this vitamin is required in the amount of 5 milligrams (mg) per day to prevent the deficiency disease pellagra, which seventy years ago was causing hundreds of thousands of people to suffer from diarrhea, dermatitis, and dementia, and then to die. What astonished me was the very low toxicity of a substance that has such very great physiological power. A little pinch, 5 mg, every day, is enough to keep a person from dying of pellagra, but it is so lacking in toxicity that ten thousand times as much can be taken without harm. Vita min C is equally lacking in toxicity. The difference between these sub stances and drugs led me to coin the word orthomolecular to describe them (see Chapter 11). The fact that a deficiency in the intake of vitamin B3 leads to the mental illness associated with pellagra caused me to check the medical literature. I found that persons with a deficiency in vitamin B12 usually become psy chotic even before they become anemic. Mental disturbances, 1 found, are also associated with deficiencies of vitamin C (depression), vitamin B1 (de
pression), vitamin B6 (convulsions), folic acid, and biotin, and there is evidence that mental function and behavior are also affected by changes in the amounts in the brain of any of a number of other substances that are normally present (Chapter 20). My interest in the vitamins was focused on vitamin C about twenty years ago by a letter I received from a biochemist named Irwin Stone. I had met him when I addressed a dinner meeting in New York City the previous month. He began his letter by reminding me that I had expressed in my lecture a desire to live for the next fifteen or twenty years. Saying that he would like to see me remain in good health for the next fifty years, he was sending me a description of his high-level vitamin-C regimen, which he had developed during the preceding three decades. My wife and I began to follow the regimen recommended by Stone. We noticed an increased feeling of well-being, and especially a striking decrease in the number of colds that we caught, and in their severity. In the introduction to my book Vitamin C and the Common Cold (1970), I wrote: “Dr. Stone was, of course, exaggerating. I estimate that complete control of the common cold and associated disorders would increase the average life expectancy by two or three years. The improvement in the general state of health resulting from ingesting the optimum amount of ascorbic acid might lead to an equal additional increase in life expectancy.” It is my opinion now, after an additional fifteen years of study in this field, that for most people the improvement in health and longevity associ ated with the ingestion of the optimum amount of vitamin C probably lies in the range of twenty to twenty-five years of well-being, with an additional increase from the optimum intake of other vitamins. As I have already conceded, I can cite no reference for this estimate, but some of the reasons I believe in it are given in the following chapters of this book. During the period 1966 to 1970 I gradually became aware of the exis tence of an extraordinary contradiction between the opinions of different people about the value of vitamin C in preventing and ameliorating the common cold. Many people believe that vitamin C helps prevent colds; on the other hand, most physicians at that time denied that this vitamin has much value in that regard. For example, in the discussion of the treatment of the common cold in his excellent book Health (1970) Dr. Benjamin A. Kogan made the following statement: “Research has shown that vitamin C, in the form of fruit juice, however pleasant, is useless in preventing or shortening colds.” Dr. John M. Adams did not mention vitamin C in this book Viruses and Colds: the Modern Plague (1967). More recent books by physicians contain statements such as the following, from What You Should Know about Health Care before You Call a Doctor by G. T. Johnson
(1975): “I would again, however, like to stress that there is no evidence to support the contention that vitamin C prevents the common cold and only shaky evidence to suggest that it may lessen the effects of colds.” In the Book of Health of the American Health Foundation (1981), edited by Dr. Ernst L. Wynder, readers are advised against taking massive doses of a particular vitamin and are told that “The evidence that taking a huge quantity [of vitamin C]—1,000 milligrams a day or more—will avert the common cold is tenuous.” There is a suggestion of a little progress, how ever, in the statement on page 578 that “Some studies indicate that rela tively large doses of vitamin G can reduce the duration of the symptoms, although the results remain controversial.” I found myself embroiled in controversy on this question by an article about vitamin C in the magazine Mademoiselle in November 1969. I was quoted as supporting the use of large amounts of vitamin C. Dr. Fredrick J. Stare, then head of the department of nutrition at the Harvard School of Public Health, who was described by Mademoiselle as “one of the country’s Big Names in nutrition,” was thereupon invoked to refute my opinion. He was quoted as saying, “Vitamin C and colds—that was disproved twenty years ago. I’ll tell you about just one very careful study. Of five thousand students at the University of Minnesota, half were given large doses of C, half a placebo. Their medical histories were followed for two years—and no difference was found in the frequency, severity, or duration of their colds. And yes, stores of C are depleted in massive, lingering infection—not in week-long colds.” The study to which Dr. Stare was referring had been carried out by Cowan, Diehl, and Baker; the article describing their results was published in 1942 (see Chapter 13). When I read this article, I found that the study involved only about four hundred students, rather than five thousand, and it was continued for half a year, not two years, and it involved use of only 200 mg of vitamin C per day, which is not a large dose. Moreover, the investigators reported that the students receiving the vitamin C had 31 percent fewer days of illness per subject than those who did not receive the vitamin. The fact that Stare, as well as the investigators themselves, had not considered a decrease by 31 percent in the days of illness to be significant suggested to me that an examination of the medical literature might provide more information about this matter. I found in the August 1967 issue of the journal Nutrition Reviews a brief, unsigned article in which a number of studies of vitamin C and the common cold were mentioned. The conclusion reported was that “there is no conclusive evidence that ascorbic acid has any protective effect against, or any therapeutic effect on, the course of the
common cold in healthy people not depleted of ascorbic acid. There is also no evidence for a general antiviral, or symptomatic prophylactic effect of ascorbic acid.” It is no coincidence that Dr. Fredrick J. Stare was listed at this time as editor of Nutrition Reviews. I examined the reports mentioned in this article and found that my own conclusions, on the basis of the studies themselves, were almost entirely different from those expressed in the article. Like the Cowan, Diehl, and Baker study, they showed a difference between the subjects given vitamin C and the control subjects in accordance with my argument for vitamin C, the difference tending to increase with the size of the dose of the vitamin administered. We may ask why the physicians and authorities on nutrition have re mained so lacking in enthusiasm about a substance that was reported four decades ago to decrease the amount of illness with colds by 31 percent, when taken regularly in rather small daily amounts. I surmise that several factors have contributed to this lack of enthusiasm. In the search for a drug to combat a disease the effort is usually made to find one that is 100 percent effective. (I must say that I do not understand, however, why Cowan, Diehl, and Baker did not repeat their study with use of larger amounts of vitamin C per day.) Also, there seems to have existed a feeling that the intake of vitamin C should be kept as small as possible, even though this vitamin is known to have extremely low toxicity. This attitude is, of course, proper for drugs, substances not normally present in the human body and almost always rather highly toxic, but it does not apply to vitamin C. Another factor has probably been the lack of interest on the part of the drug companies in a natural substance that is available at a low price and cannot be patented. This is a pity; for here is a substance that holds the possibility of eliminating the common cold from human experience. An old friend of mine, Rene Dubos, pointed out in one of his books that it is not the viruses and bacteria we are exposed to that kill us—something else kills us. When there is an epidemic, some people die and other people do not die. What is the difference between them? It is this difference that kills. I believe that often it is too little vitamin C that permits some people to succumb. The common cold, and influenza as well, are infections by viruses that circulate, sometimes in epidemics, throughout the world. They rapidly die out, however, in a small, isolated population. If the incidence of colds and influenza could be decreased enough throughout the world—as it might be by the use of vitamin C for prevention and therapy—these diseases would disappear. I foresee achievement of this goal, perhaps within a decade or two, in some parts of the world. Some period of quarantine of travelers
might be needed, so long as a major part of the world’s people are povertystricken and especially subject to infectious diseases because of malnutri tion, including lack of ascorbic acid in the proper amount. To achieve this goal a change in the attitude of the public and of patients may be required. A person with a cold or the flu should feel that he or she should go into isolation in order not to spread the virus to other people, and social pressure should operate to help him or her to act in such a way as not to harm others. We have recently experienced a change in feeling about the “right” of cigarette smokers to pollute the atmosphere and distress non smokers. A similar change in feeling about the “right” of people to spread their viruses and infect others, so long as they themselves are able to stagger about, would benefit the world. After twenty years of research and public education in the new nutrition, I believe that I can detect some progress in the attitude of the medical profession toward the new nutrition’s findings and recommendations. De spite the intransigence of official opinion, I see the attitude of practicing physicians toward ascorbic acid and the other vitamins undergoing signifi cant change. They are responding to the new evidence that has been gath ered, some of which I review in this book. It is being more widely recog nized that the intake of vitamins, and of some nonessential nutritional factors as well, can be varied in such a way as to produce a significant improvement in general health and a decrease in the incidence and severity of disease. Ultimately, it will be common knowledge that the optimum daily intakes of vitamins are far larger than what can be had in food, even by selecting foods for their high vitamin content. The major reason argued for eating fruits and vegetables is to obtain vitamins. The availability of vitamins does not mean that you should not include fruits and vegetables in your diet. It is true that for more than eighty years science-fiction writers have been writing about a world of the future in which people would not eat ordinary food but instead would swallow a tablet or two each day. We have now gone part-way toward this goal in that the need to eat large amounts of fruits and vegetables in order to have enough vitamins to keep us alive has been eliminated. By taking a few vitamin tablets we can obtain not only the minimum requirement that may be furnished by the natural foods eaten in sufficient quantity but the opti mum intake that puts and keeps us in the best of health. We may ask how much further modern nutritional science and molecular biology might take us. The answer is that our nutritional needs can never be met by a few tablets per day. A rather large amount of fuel is required to provide the energy to keep us warm and to run the biochemical processes in our bodies
that permit us to function and to work. That requirement comes to about 2500 kilocalories of food energy per day. To obtain this much food energy, about 1 pound, dry weight, of starch or the sugar glucose must be ingested. What is more, the body requires certain fats it does not itself manufacture, and it must be supplied with protein to replace the protein of its principal working parts as they wear out in the course of a day. A diet of this sort is available, as will be discussed in the next chapter, and it consists of much more than a few tablets.
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Living organisms require daily intake of nutrients, substances from outside the body that, ingested and assimilated in the tissues, permit growth and preserve good health, provide energy, and replace loss. Certain substances are required in large amounts. These are the macronutrients; they are four in number: proteins, fats, carbohydrates, and water. Other substances, the micronutrients, are required in small amounts: certain minerals, the vita mins, and the essential fats and essential amino acids (building blocks of protein). The latter are called essential because the organism does not man ufacture them, although it manufactures other fats and amino acids. In this chapter, in a book otherwise concerned with one class of micronutrients, we consider the macronutrients, taking them in the order in which they are listed above. The human body contains tens of thousands of different proteins, which serve different purposes. Hair and fingernails consist of fibers of a protein called keratin; muscle is composed of fibers of myosin and actin. Another fibrous protein, collagen, strengthens the skin, blood vessels, bones, teeth, and the intercellular cement that holds the cells in various organs and tissues together. Globular proteins, in solution in the body fluids, serve as enzymes to speed up the chemical reactions that are essential to life. Cer tain proteins serve other special functions. Hemoglobin, for example, the
red protein in the red cells of the blood, carries molecules of oxygen from the lungs to the other parts of the body, where it is used to burn molecules of food in order to provide energy. Proteins are long chains of amino-acid residues. There are more than twenty different amino acids. The nature of the protein is determined by the sequence of these different amino acids in the chain. Amino acids are rather small molecules, consisting of between ten and twenty-six atoms of hydrogen, carbon, nitrogen, oxygen, and sulfur; at least one of the atoms is nitrogen, as shown in the illustration in Chapter 9. Most protein chains contain a few hundred amino-acid residues. The molecule of adult hemoglobin contains four chains, two with 140 residues and two with 146 residues each. As might be expected for structural mole cules, proteins are characterized by the arrangement of their component amino acids in the three dimensions of space as well as by the sequence of the residues in the chain. The simplest, natural three-dimensional structure assumed by a chain of identical asymmetrical amino acids, bonded head to toe at the same angle, is the so-called alpha helix (see illustration in Chap ter 9). In hair, the keratin chains are coiled in the alpha helix, like a spring. In a globular protein such as hemoglobin or the digestive enzyme trypsin, there are straight segments, alpha-helix coils, but the chain folds back on itself to become nearly spherical. In silk the chains are stretched out to nearly their maximum length. The amino-acid sequence for the same proteins in different animals is different. All mammals have hemoglobin in the red cells of their blood, but the hemoglobin molecules are different in their amino-acid sequence. Be cause of the difference in the blood proteins (and also the blood carbohy drates) of different animals we cannot safely transfuse blood from another species of animal into a human being. As Dr. Karl Landsteiner discovered in 1900, the blood of different human beings also may be different in such a way as to make transfusion of blood from one person to another dangerous to the recipient, unless tests have shown that the two persons have the same blood type. When the food that we eat is digested in the stomach and intestines the protein molecules are broken down by the digestive enzymes into their component amino acids. The protein molecules in the food (from meat, fish, vegetables, grains, cheese, and milk) are so large that they cannot pass through the intestinal walls into the bloodstream, but the small molecules of the amino acids and of glucose from the breakdown of the long carbohy drate chains of starch can pass through. The blood carries these small molecules to the tissues throughout the body. They enter the cells, and the amino acids are then reassembled into long chains with the sequences that
are characteristic of human proteins, under the guidance of the molecules of deoxyribonucleic acid (DNA) in the nuclei of our tissue cells that determine our nature. Our bodies are continually wearing out and being renewed. For exam ple, our red cells live only about one month. They are then broken down, and the hemoglobin molecules are split into amino acids. Some of the amino acids are used to make new protein molecules, but some are oxidized to water, carbon dioxide, and nitrogen-containing urea, which is excreted in the urine. Because some of the amino acids are used as fuel in this way, our bodies can keep in amino-acid balance (usually called nitrogen balance) only by adding some amino acids; that is, by eating some protein. With too small an intake of protein a child will stop growing, and a child or adult may die of protein starvation, even when the intake of fat and carbohydrate is adequate. Protein starvation is called kwashiorkor (from an African word in a region with a high-corn diet). Marasmus is energy starvation, and marasmus-kwashiorkor involves both deficiencies in the diet. These dis eases cause many deaths in the overpopulated and underdeveloped coun tries and some in the affluent countries. The amount of protein required for amino-acid balance for an adult is proportional to body weight. It is about 0.45 grams (g) per kilogram (kg), 0.20 g per pound. The Food and Nutrition Board recommends 30 percent larger amounts, 0.26 g per pound for adults. Infants need about 1.0 g per pound, young children about 0.60 g per pound, older children and adoles cents 0.50 or 0.40 g per pound. Most adult Americans ingest two or three times the recommended amount of proteins. The excess not required for building new protein mole cules is burned, for energy, along with the fats and carbohydrates, and probably no harm is done by the excess intake to people in reasonably good health. A high intake of protein means that a large amount of urea must be excreted in the urine. The excretion of urea requires work by the kidney, and increased intake of protein increases the burden on the kidney. People with impaired kidney function, such as those with only one kidney or who have suffered damage from nephritis, can avert further kidney damage by limiting protein to the amino-acid-balance level. Care must be taken not to go below this level. Although all of the amino acids are present in the proteins in the human body, not all of them need to be in the food because most of them are manufactured by the body. Those that must be obtained in the food, the essential amino acids, are histidine, leucine, isoleucine, lysine, methionine, phenylalanine, threonine, tryptophan, and valine. The amounts required for an adult young man range from 0.50 g per day for tryptophan to 2.20 g
per day for leucine, methionine, and phenylalanine. These amounts are provided by a mixed diet including animal protein (meat, fish, eggs) but not by a vegetarian diet, which may be especially low in lysine and methionine. Everybody knows what fat is—hog fat (lard) and beef or sheep fat (tal low). It has a greasy feel, is insoluble in water, and is an important con stituent of foods and of the human body. Its chemical nature was discovered about 1820 by the French chemist Michel Eugene Chevreul, who died in 1889, at age 103. (I assume that he was not fat, or he would not have lived so long.) The Roman author Pliny the Elder mentions in his book on natural history that the Germans were making a soap solution by boiling fat with the ashes of plants (potash). In 1779 the Swedish chemist K. W. Scheele discovered that a detergent solution contained not only soap, the potassium salt of a fatty acid, but also an oily, sweet-tasting, water-soluble liquid that we now call glycerine or glycerol. Clevreul discovered that ordinary fats consist of glycerol with three mole cules of a fatty acid attached. A representative fat is glyceryl tripalmitate; its atomic composition is diagrammed this way: H 2G— OOC(CH2) 14CH 3 HC—OOC(CH2) 14GH3 H 2G— OOG(GH2) 14CH 3
This fat is said to be “saturated” by hydrogen (H) because hydrogen atoms occupy the four bonds of each carbon (C) atom that are not attached to other carbon atoms or to oxygen (O). Other saturated fats have a smaller or larger number of CH2 groups in the hydrocarbon side chains. Unsaturated fats have fewer hydrogen atoms; that is, they are not saturated with hydro gen. There are more unsaturated side chains in liquid fats (oils) than in solid fats. These fat molecules are called triglycerides. When you receive a report on the analysis of your blood, there may be values for total cholesterol, HDL, LDL, and triglycerides. The amount of triglycerides is nothing other than the amount of fat in the blood plasma. Cholesterol, HDL, and LDL are molecules made by the processing of fat. Fat is an important constituent of the diet as a source of metabolic en ergy. It also has value in helping to move the fat-soluble vitamins across the intestinal wall into the bloodstream. In 1929 it was discovered that young rats show slow growth, kidney deterioration, and infertility on a diet containing only saturated fats. Be tween 1930 and 1956 different investigators discovered seven unsaturated
fatty acids that are necessary, essential, in small amounts for normal growth and life for rats and other animals. Presumably human beings also require intake of these essential fatty acids. Only a few observations have been made on human beings on a very low fat diet; they showed an abnor mal basal metabolism rate, increased incidence of infections, and a tendency to dermatitis. It is believed that a diet containing the usual amount of fat provides sufficient amounts of the essential fatty acids. There is some evi dence, however, that an increased intake of two of them, linoleic acid and gamma-linolenic acid, may have protective value against atherosclerosis and cancer. Carbohydrates were given this name because chemists noticed that these substances (various sugars, starch, glycogen, and cellulose) have formulas C + H20 , that is, hydrated carbon. For example, glucose and fructose are C6H 120 6, sucrose is C12H 220 12. In fact, there are no water molecules in these substances; instead, there are carbon atoms and one or two hydro gen atoms attached to them along with the oxygen atoms and hydroxyl groups (OH). Starch is the principal carbohydrate food. It is found in all fruits and vegetables. An intake of 300 g would provide 50 percent of an average daily requirement of energy. Providing energy is the principal function of the carbohydrates in our food. Many fruits and some vegetables also contain significant amounts of the simple sugars glucose and fructose, as well as the disaccharide sucrose, ordinary sugar, which contains both glucose and fructose. When starch is digested by the enzymes in the saliva and gastric juice, it combines with water and breaks down to form the small molecules of glucose, which pass through the walls of the intestines into the bloodstream and are transported to the cells all over the body. There they are burned to provide the energy that we need to operate our biochemical mechanisms, to do work, and to keep warm. The glucose that is present in foods also enters the bloodstream and is handled in the same way. Human beings and their predecessors have been accustomed to metabolizing about 300 g of glucose (mostly from starchy foods) every day for millions of years. The situation with fructose is different from that with glucose. Human beings have always ingested some fructose, in the fruits and honey that were part of their diet. Until about two hundred years ago the average daily intake of fructose was quite small, only about 8 g. Then, as ordinary sugar (sucrose) from sugar beets and sugarcane began to be generally avail able the daily intake of fructose rose tenfold, to about 75 g per day. The reason for this great increase in the intake of fructose is that when sucrose is ingested it reacts with water to form equal amounts of glucose
and fructose. Each 100 g of sucrose gives 53 g of glucose and 53 g of fruc tose; that is why it is referred to as a disaccharide. In the United States we eat about 100 pounds of sugar (sucrose) per year. This is 125 g per day, corresponding, when it is digested, to 66 g of fructose per day. With about 8 g from fruits and honey, the average daily intake becomes 74 g per day. Our bodies have been accustomed to metabolizing only 8 g of fructose per day. It is accordingly not surprising that the nearly tenfold overload causes problems. There is little doubt that this great intake of fructose, to which human beings have been subjected only during the last century, is the cause of many of our ills, as will be discussed in Chapter 6. Water is the fourth major nutrient. It is required for life in the amount of about one liter (1) per day, partially to produce urine to carry off the harmful substances that have been extracted from the blood by the filtering processes that operate in the two million filtering units (nephrons) in the kidneys. A larger intake of water, preferably about 3 1 (more than 3 quarts) per day, is needed for the best of health. A good habit is to drink a glass of water every hour. Soft drinks provide water, but they are undesirable be cause of the sugar or the sugar substitutes that they contain. Carbonated water, orange juice, and other fruit juices are good sources of water, as is also beer, in limited amount. One reason for a high intake of water is that it leads to a high volume of urine; this reduces the burden on the kidneys, which excrete a dilute urine with less work than they do a concentrated urine. That is especially impor tant for persons with impaired kidney function. Another reason is that with a high intake of water there is less chance that crystals of one kind or another will form out of the body fluids. Gout results from the formation of crystals of sodium urate in the joints and tendons, and pseudo-gout from the similar crystallization of calcium pyrophosphate dihydrate. Urinary calculi (kidney stones) involve the for mation of masses of crystals held in a protein matrix. The crystals are calcium and magnesium phosphates and urates or, less commonly, cystine. About 1 percent of people have a tendency to form these stones. The forma tion can be averted by keeping the water intake high, never allowing the urine volume to drop. The various classes of foods—meats, fish, fruits and vegetables, grains and nuts, dairy products—all have value in providing protein, fat, carbo hydrates, minerals, vitamins, and other valuable micronutrients, such as gamma-aminobenzoic acid, choline, lecithin, and the ubiquinones. The amounts of these important constituents are different in different foods, and it is wise to have a varied diet, one that appeals to you, and to supplement it with the important vitamins and minerals in order to get them in the optimum amounts.
The servings of meat and fish must be kept small in order to keep the total protein intake down to the recommended amount, 0.8 g per kilogram body weight. Ovolactovegetarians, who accept eggs and milk but not meat and fish, can keep in good health by taking supplementary vitamins and minerals. Strict vegetarians need to select their vegetable foods with care to insure that they have the proper intake of those vegetables that provide the essen tial amino acids that are present in only small amounts in most vegetable foods. The intake of fat should be limited, but enough should be eaten to pro vide the essential fats. Fruits, vegetables, grains, and nuts should be eaten in a satisfying variety and amount. Fruits and vegetables provide some protein and fat, large amounts of carbohydrates, and also vitamins, minerals, and other micro nutrients. A high intake was needed in past centuries in order to provide the minimum amounts of these micronutrients, as well as carbohydrate for energy. In the new era of modern nutrition the optimum intakes of vita mins, more than can conveniently be provided by fruits and vegetables, are available in supplements, as discussed throughout this book. It is wise, nonetheless, to supplement the vitamin supplements with a good intake of fruits and vegetables. Seeds and nuts are low in vitamins and high in protein and fat as well as carbohydrate and total energy. For example, a 1-ounce snack of almonds provides 180 kilocalories (kcal) of food energy, 5 g of protein, 16 g of fat, and 6 g of carbohydrate. A similar snack of peanuts provides 170 kcal of energy, 7 g of protein, 14 g of fat, and 5 g of carbohydrate. The amount of carbohydrate eaten should be kept down to the amount that permits the ingested fat to be burned rather than deposited in the body. You may have to limit your consumption of alcohol and of nuts and other snacks, as well as the size of your meals. The intake of sucrose (white sugar, brown sugar, raw sugar, honey, candy, sweet desserts) should be kept low. Corn syrup consists of glucose, and it is an acceptable sweetener unless sucrose has been added to make it sweeter—check the label. The obesity and atherosclerosis, the two most common nutritional afflictions arising from bad habits with respect to the macronutrients, that follow upon violation of these simple rules are discussed in Chapter 6.
5.F o o d s H
a s
e a t
th e a n d
S o u r c e
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E n e r g y
One of the characteristics of human beings is that they are able to do work. They also are able to keep warm in a cold environment. A source of energy is required for doing work and keeping warm. Many of the substances in our food that enter the bloodstream—the fats and the amino acids as well as the carbohydrates—are burned in the cells of our tissues and organs to provide the energy for various biochemical reac tions, including those in our muscles that permit us to do physical work and those that generate the heat energy to keep us warm. This process of burn ing is the enzyme-catalyzed combination of the fuel molecules with oxygen molecules that are distributed through the body by the blood. The hydrogen atoms burn to water, H zO, and the carbon atoms to carbon dioxide, C 0 2, which is carried to the lungs and exhaled. The nitrogen atoms form urea, H 4N2CO, which is excreted in the urine. The average amount of food energy required by men is 2000 to 3500 kilocalories (kcal) per day and for women 1600 to 2400. Young people require more and old people less. The quantity 2500 kcal is the average daily amount. This amount of energy could heat a bathtub full of water (increasing the temperature of 25 gallons of water from 50°F to 100°F). If it could all be used to do work, it could lift a weight of 1400 pounds to the top of a mile-
high mountain. With these calculations in mind, we can understand that we need more food in the winter than in the summer, in cold climates than in warm climates, and that heavy physical work or strenuous exercise in creases the need for food. The concept of food energy was discovered in 1842 by a young German physician, Julius Robert Mayer (1814-1878). He was the ship’s surgeon on a Dutch ship sailing to Java when he wondered why the sailors, who were doing just as much work every day, ate much less food in the Indian Ocean than in the North Sea, and why the hard-working sailors ate more than the officers. He concluded that the food that a person ingests provides a certain amount of energy, which can be used either for heat or for work. At the same time the English physicist James Prescott Joule was making experiments (reported in 1843) to determine the relation between work and heat. These two thoughtful persons discovered the very important physical law called the conservation of energy. The energy values of a food can be determined by burning a weighed amount of the food and measuring the amount of heat given off. It is convenient to give the values for a standard amount, 100 grams (g, or 3V2 ounces) of the food. The energy values are 900 kcal per 100 g of fat, 415 kcal per 100 g of starch, and about 430 kcal per 100 g of protein. The values for the sugars are a little smaller than for starch: 395 kcal per 100 g for sucrose, lactose (milk sugar), and maltose (malt sugar, a disaccharide made from starch by action of an enzyme), and 375 kcal per 200 g for glucose and fructose. In the table below there are given values of the fractions of the energy provided by fat, protein, and carbohydrate in several diets—the average American diet, the diet recommended by the U.S. Senate Select Committee on Nutrition and Human Needs, and an intermediate diet. The third diet contains more fat and less carbohydrate than that of the Senate Committee. Energy distribution of some diets. Present U.S. diet Fat Protein Carbohydrate Starch Naturally occurring sugars Sucrose TOTAL
42% 12% 46% 100%
20% 6% 20%
Dietary goal'
Intermediate diet
30% 12% 58% 38% 10% 10% 100%
40%(1000 kcal/day) 10%(250 kcal/day) 50%(1250 kcal/day) 30% 10% 10% 100%(2500 kcal/day)
1D ieta ry G oals Jor th e U n ite d S tates. Senate Select Committee on Nutrition and Human Needs. U.S. Government Printing Office, Washington, D.C. (1976).
Part of the reason for recommending the intermediate amount of fat is that we need the essential fats, and we obtain these essential fats almost entirely in the food that we eat. A diet with 10 percent of the energy provided by protein and giving 2500 kcal requires 58 g of protein. To keep the protein intake down to this level requires that the intake of meat and fish be limited. Half a pound of beefsteak provides more than 58 g of protein, allowing for no other protein foods. One egg provides 6 g; one glass of milk 8 g; one slice of bread 3 g; one serving of baked beans 8 g; one serving of potatoes, green beans, or other vegetable 2 to 6 g; a serving of breakfast cereal 4 to 8 g. Lamb, pork, and fish contain 15 to 20 percent protein, beef about 30 percent. The intake of meat and fish should be kept to about a quarter of a pound per day. Probably the greatest benefit of all offered by the recommended diet comes from decreasing the intake of sucrose, ordinary sugar, as is discussed in the next chapter. Much interest in the value of meat in the diet was created over half a century ago by observations made by the Arctic explorer Vilhjalmur Stefansson. He was born in Manitoba, Canada, of Icelandic parents, in 1879, and when he was only a year or two old he (and his parents) lived mainly on fish for a year, because of a famine in the area. After graduating from the University of Iowa, studying anthropology for three years at H ar vard, and making two archaeological trips to Iceland, he began his Arctic research in 1905. He lived with the Eskimos for a year, learning their language and culture, and he concluded that it was possible to remain in reasonably good health on the Eskimo diet of meat alone, eaten as the Eskimos eat it. By 1926 he had lived a total of nine years on a meat-only diet, during 11 and a half years spent in the arctic. The longest period that he ate no food other than meat was nine months. A study of him made in 1922, when he was forty-three, showed him to be in the state of health expected for his age (Lieb, 1926); for example, his blood pressure was 115/55. He died at the age of eighty-two. Because of Stefansson’s claim that it was possible to be healthy on a diet of meat only, a carefully planned experiment was carried out with Stefansson and another arctic explorer, beginning in 1927. For one year the two men ate nothing but meat (beef, lamb, veal, pork, chicken, both fat and lean portions, and also at times liver, kidney, brain, bacon, and bone mar row). Stefansson also ate some eggs, butter, and fish, when he had trouble obtaining meat while traveling. The meat was usually boiled or stewed, but they ate some raw marrow. They drank no milk. They were in a hospital under observation for the first six months and then resumed their usual activities but adhered to their diet. They reported that they had no craving
for other foods. They complained, however, that the boiled mutton was not so good as the musk ox, caribou, or mountain sheep described in Stefansson’s autobiography, Discover (1962). They were carefully studied throughout the year, with the conclusion that they were in as good health at the end of the year as at the beginning. The diet contained about 230 g of fat, 120 g of protein, and only 5 to 10 g of carbohydrate per day. The high intake of animal fat did not seem to harm them (Torry and Montu, 1931). Their tolerance for glucose was low at the end of the year but became normal within two weeks on a mixed diet. It is remarkable that they did not develop vitamin-deficiency diseases on the exclusively meat diet. Presumably fresh meat contains a minimum sup ply of vitamin G and other vitamins. Stefansson (1918) reported that three of the seventeen members of the Canadian Arctic Expedition became scorbutic during the winter of 1916-1917. These three had been eating some foods in a cache that had been left by an earlier expedition. They developed scurvy, whereas the others, who ate only fresh meat, did not. I do not conclude that a meat diet is the best, even though fresh meat may alone provide the minimum amounts of all nutrients, with the fat providing most of the energy. Vitamin supplements and a mixed diet, with a limited intake of sugar, lead to the best health. Stefansson’s experience has its relevance to public anxiety about fat in the diet. That anxiety was awakened in 1955, when President Dwight David Eisenhower suffered a coronary occlusion. The president’s cardiolo gist, Paul Dudley White of the Harvard Medical School, took the occasion to instruct the public about the role of cholesterol in atherosclerosis and to advise reduction in the intake of fat-containing foods. Stefansson was moved to challenge White with his own good health on a high-fat diet and his observations of the health of the Eskimos he knew so well. He con cluded with the rhetorical question: “We eat carbohydrates, fat, and pro tein. We make gunpowder from saltpeter, sulfur, and charcoal. How can we say which one makes the explosion?” White withdrew his doctrinaire stricture and wrote a chastened introduction to a new edition of Stefansson’s account of his dietary adventures published under the title The Fat of the Land. The energy content of alcohol is discussed in the following chapter.
6.T w
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P r o b le m
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It is from the numerous deficiency diseases, caused by lack of essential elements in the diet, that the students of nutrition first learned about the micronutrients and the various ways in which they serve the healthy orga nism. Today, in the well-off and well-fed industrial countries of the world, the science of nutrition is learning to contend with afflictions that attend overabundance rather than deficiency of the macronutrients. Efforts to manage the two most common of these afflictions, obesity and atherosclero sis3 generate more controversy, if that is possible, than that which attends discussion of the micronutrients, especially the vitamins. Obesity is the condition of being grossly overweight, excessively fat, much beyond the normal weight for the person’s height and build. It consti tutes a serious problem for many people. The normal weights for women between 5 feet and 6 feet tall are 116 to 155 pounds, with leeway of about 10 or 15 pounds each way, depending on build. For men between 5 feet 4 inches and 6 feet 4 inches the values are 135 to 185 pounds, with leeway of 15 to 20 pounds. Overweight by 25 percent is accompanied by some inconvenience, by 40 percent increased incidence of illness, and by shortening of life expectancy by four years. Overweight by 50 percent causes much inconvenience, a more than doubled incidence of illness, and a ten-year decrease in life expectancy (Pauling, 1958).
In past centuries and millennia the deposition of fat in the human body has served an important purpose. The supply of food was often irregular. When plentiful food was at hand, as when a mastodon was killed, people ate as much as they could. The protein (excess amino acids) and carbohy drates (glucose) were burned in the body cells to provide the needed energy, and the fat was stored in deposits under the skin and elsewhere in the body, in order that it might be burned later, to prevent death by starvation when food became scarce. We may conclude that the way to prevent the excessive deposition of fat is to restrict the intake of all food—protein, carbohydrate, and fat—to the quantity required every day for heat and work. There is little gain from restricting just one kind of food. Even if fat is restricted, there is still some fat in the diet, and if there is enough carbohydrate to provide the energy needs, this fat will be deposited and will lead to obesity. No crash diet or fad diet can solve the obesity problem, because these diets are so disagreeable and such a continuing nuisance that the obese person soon gives up. A successful treatment is one that will be adhered to, year after year. To achieve such continued compliance the diet should ap peal to the appetite. It is not the kind of food that controls the body weight, but it is instead the total food energy, in relation to size, build, and amount of exercise. The food should be the kind that pleases the person, but the amounts eaten must be limited. This point has been emphasized by Brian Leibovitz in his 1984 book, in which he criticizes various fad diets for control of weight and improvement of health. Representative of his comments are his statements about the Pritikin diet. On the jacket of Nathan Pritikin’s book The Pritikin Promise: 28 Days to a Longer, Healthier Life there is the following exhortation: Follow my safe 28-day diet and exercise program and I promise you: You’ll feel really alive every day; You’ll reduce risk of heart disease, diabetes, high blood pressure, breast and colon cancer; You’ll lose weight without hunger. Leibovitz comments: The Pritikin program is a low-protein, low-fat, and highcarbohydrate regimen, and to its credit it emphasizes the importance of unrefined foods. Oil, butter, salt, sugar, and red meats are not allowed on the Pritikin plan. Since neither butter nor oils are allowed, foods must be broiled or steamed. The Pritikin diet, while basically
sound, suffers from two major drawbacks, however. To begin, it is unnecessarily Spartan. Although there are some good reasons to cut down on excessive consumption of meat, dairy products, oil, butter, salt, and sugar,... it is not necessary to eliminate them entirely from the diet. In my experience, because it is so strict, many who try the Pritikin diet have trouble staying on it. The moral is: do not be extreme; for example, do not adopt a single-food diet, such as the Zen Macrobiotic diet, which involves eliminating foods until only brown rice is eaten. Adhering to such a diet can result in death. Instead, adopt eating habits that are sensible and also satisfying to you, so that you can adhere to them year after year. A common tragic outcome of faddism in dieting and the anxiety caused by the difficulty of observing fad diets is the anorexia nervosa that seizes adolescent girls. It is estimated that between 5 and 20 percent of adolescents (95 percent female) with anorexia nervosa die of protein, energy, and vita min starvation. Often the young person has a voracious appetite (called bulimia), but a large meal is followed by induced vomiting. This disease, which is not associated with poverty or scarcity of food, seems to be psycho logical, the result of a fear of becoming overweight. Anorexia nervosa is a serious disease. The patient requires expert treatment, including psychotherapy. Many actions can be taken to improve one’s health without interfering seriously with the enjoyment of life. A sensible control of the diet is one such action. Another is the regular use of dietary supplements, which is the theme of this book. One point that must not be forgotten in weight control is that alcohol is a food. Potable alcohol, ethanol (C2H 5OH), has a rather high heat of com bustion, 700 kilocalories (kcal) per 100 grams, closer to that of fat (900) than of carbohydrate (400). One jigger (1.5 ounces) of strong liquor (80 to 100 proof) provides 100 to 120 kcal. One pint of beer provides 160 kcal. One glass of wine provides 100 to 150 kcal. Accordingly a moderate drinker, inbibing two or three drinks a day, may receive 300 to 400 kcal of food energy from the alcohol, and a heavy drinker may receive 1000 to 1500 kcal, as much as one half of the daily energy requirement. One result is that heavy drinkers get fat. Moreover, even moderate drinkers have an added tendency toward obesity. To lose weight you must cut down on your intake not only of protein, carbohydrate, and fat, but also of alcohol. Another effect of a high intake of alcohol is that the drinker doesn’t eat very much and may begin to suffer from a deficient intake of vitamins and
minerals, unless he or she takes vitamin-mineral supplements. In a study of randomly selected residents in San Mateo County, California, H. D. Chope and L. Breslow found that moderate drinkers are healthier than teetotallers but that heavy drinkers, who consume more than four drinks per day, are less healthy. Part of their poor health may be the result of vitamin-mineral malnutrition. Especially in this country, there are few people who have not heard that the diseases of the heart and circulatory system, the number one cause of death, have been associated with fat in the bloodstream. With this knowl edge in mind, almost everyone accepts the further proposition, advanced by many physicians and most nutritionists, that high concentration of fat in the bloodstream is caused by high intake of fat in the diet. John Yudkin, professor of physiology in Queen Elizabeth College of London University (1945-1954), professor of nutrition and dietetics (1954— 1971), and now emeritus professor of nutrition, has a different view of the matter. He has presented his view in a series of scientific papers and in the book Sugar: Chemical, Biological, and Nutritional Aspects of Sucrose, edited by Yudkin, Edelman, and Hough (1971). He has summarized his findings for the lay public in his book Sweet and Dangerous (1972). Yudkin traced the widely held theory about fat to a paper by Ancel Keys, of the University of Minnesota. “In 1953,” wrote Yudkin, Keys “drew attention to the fact that in six different countries there was a highly sug gestive relationship between the intake of fat and their death rates from coronary disease. This was certainly one of the most important contribu tions made to the study of heart disease. It has been responsible for an avalanche of reports by other research workers throughout the world; it has changed the diets of hundreds of thousands of people; and has made huge sums of money for producers of foods that are incorporated into these special diets.” Against the general public acceptance of the proposition that coronary heart disease is caused by a high intake of animal fat (saturated fat) and the eating of foods containing cholesterol, Yudkin himself has shown that for the same countries the correlation of coronary disease with intake of sugar is much better than that with intake of fat. He found that persons who develop coronary disease have been ingesting more sucrose, ordinary sugar, than those who have not developed the disease, and he remarks that “no one has ever shown any difference in fat consumption between people with and people without coronary diseases, but this has in no way deterred Dr. Keys and his followers.” Yudkin’s observation has been confirmed by a largescale, long-term epidemiological study of the population of Framingham, Massachusetts, conducted under the auspices of the National Institute of
Health, which showed no correlation between the intake of fat and the incidence of heart disease. Nevertheless, perhaps in part because of the now huge economic interest in the link between fats in the food and cholesterol in the blood, the naive one-to-one correspondence persists in physicians’ advice and in the public mind. The idea is dying hard, as we shall see in Chapter 16. Coronary heart disease, which occurred very rarely seventy-five years ago, is today one of the principal causes of death. In 1957 Yudkin reported a study of the death rate from coronary disease in fifteen countries in relation to the average intake of sugar. The annual coronary death rate per 100,000 persons increases steadily from 60 for an intake of 20 pounds of sugar per year to 300 for 120 pounds per year, and then more sharply to about 750 for 150 pounds per year. In 1964 and 1967 Yudkin and his
coworkers reported the results of two studies of the average intake of su crose (during the period of some years before they had developed the dis ease) of sixty-five male patients in London with myocardial infarction or peripheral arterial disease, and also of fifty-eight male control subjects, of whom some were healthy and some were patients hospitalized with other diseases. The patients with heart disease were 45 to 65 years old, with average 56.1, and the control subjects were in the same age range, with average 55.1. The mean sugar intake of the men who developed cardiovascular disease was 140 pounds per year, and that of the controls was 80 pounds per year. This difference has very high statistical significance, the calculated confi dence level being greater than 99.999 percent. We are led to the conclusion that men with a large intake of sucrose have a far larger chance of develop ing heart disease in the age range forty-five to sixty-five than those with a small intake of sucrose. A second study gave essentially the same results. Yudkin’s work has been criticized on the ground that his method of determining the intake of sucrose, by questioning the patient, within three weeks after his hospitalization, about his normal eating habits, was un reliable. He carried out an investigation to check this point and concluded that this method is as reliable as the much more elaborate method usually used by nutritionists. Coronary disease, including angina pectoris, which because of its striking symptoms would surely not have been ignored by the physicians of earlier centuries, seems to be a disease of modern times. It has been reported in the medical literature only during the last hundred years. The increasing inci dence of the disease closely parallels the increasing consumption of sugar. It is not at all correlated with the consumption of animal fat (saturated fat) or of total fat. Yudkin quotes several studies that indicate strongly that sucrose, and not animal fat, is the villain in the heart-disease story. Dr. A. M. Cohen in Jerusalem found that Yemenite Jews who had been in Israel only ten years or less had very little coronary disease, whereas those who had been in Israel twenty-five years had a high incidence of the disease. In the Yemen their diet had been high in animal fat and low in sugar, and in Israel they had adopted the usual high-sugar diet of the country. This observation shows clearly that a diet high in saturated fat does not necessarily lead to a high incidence of coronary disease, and it supports Yudkin’s conclusion that a high-sucrose diet does lead to coronary disease. Moreover, the East African Masai and Sumburu tribes live mostly on milk and meat and accordingly have a high consumption of animal fat; nevertheless, they have very little heart disease. In the past the black popu lation in South Africa as a whole had almost no coronary disease; during
the last ten years their consumption of sugar has increased greatly, and the incidence of coronary disease is rising rapidly. The epidemiological evidence that there is a correlation between the amount of cholesterol in the blood, if not in the diet, and the incidence of heart disease is convincing. When the level of cholesterol is decreased, the incidence of coronary disease decreases. The procedure that has been rec ommended to decrease the level of cholesterol is to cut down the intake of eggs, meat, and other foods that contain cholesterol. The cholesterol in gested in food does not, however, go directly into the bloodstream. It may be that another procedure is even better than reducing the intake of choles terol. This procedure is to change our intake of nutrients that are known to be involved in the synthesis and destruction of cholesterol in our bodies. Yudkin has convincingly put the sugar sucrose in this category. As explained in Chapter 4, the metabolism of sucrose yields in its first step equal quantities of glucose and fructose. Glucose proceeds directly into the metabolic steps that yield its energy to the biochemical machinery of the cells of the body. Fructose metabolism goes in part by a different route such that it produces acetate, which is a precursor of the cholesterol that we synthesize in our liver cells. It has been shown in a trustworthy clinical study that the ingestion of sucrose leads to an increase in the cholesterol concentration in the blood. This important study was reported by Milton Winitz and his associates in 1964 and 1970. These investigators studied eighteen subjects, who were kept in a locked institution, without access to other food, during the whole period of the study (about six months). After a preliminary period with ordinary food, they were placed on a chemically well-defined small-mole cule diet (seventeen amino acids, a little fat, vitamins, essential minerals, and glucose as the only carbohydrate). The only significant physiological change that was found was in the concentration of cholesterol in the blood serum, which decreased rapidly for each of the eighteen subjects. The aver age concentration in the initial period, on ordinary food, was 227 milli grams per deciliter. After two weeks on the glucose diet it had dropped to 173, and after another two weeks to 160. The diet was then changed by replacing one quarter of the glucose by sucrose, with all of the other dietary . constituents kept the same. Within one week the average cholesterol con centration had risen from 160 to 178, and after two more weeks to 208. The sucrose was then replaced by glucose. Within one week the average cholesterol concentration had dropped to 175, and it continued dropping, leveling off at 150, 77 less than the initial value (see the illustration on page 43). This important experiment, in which the only change made was to re place some of the glucose in the diet with sucrose and then return to the
STAGE 1
Weeks
Cholesterol in the blood In a locked ward eighteen male experimental subjects received at first ordinary food and then a rigorously specified diet in which protein requirements were met by amino acids, the bulk requirement by essential fats, and the carbohydrate requirement by glucose. Four stages in the experiment are charted here. STAGE 1: For the first four weeks the subjects ate ordinary food. STAGE 2: From the fourth to the eighth week, their diet contained only glucose as carbohydrate. STAGE 3: From the eighth week to the twelfth week, their source of carbohydrate was mixed: 75 percent glucose and 25 sucrose. STAGE 4: After the twelfth week, their diet returned to glucose (as in stage 2). Note that their blood cholesterol decreased significantly each time the sucrose was eliminated.
sucrose-free diet, shows conclusively that an increased intake of sucrose leads to an increased level of blood cholesterol. Because of the relation between bloodstream cholesterol and heart disease, this experiment ties the consumption of sucrose directly to increased incidence of heart disease. Moreover, the sucrose-cholesterol effect has its biochemical basis estab lished in the fact that fructose, formed in the digestion of sucrose, undergoes reactions in the body leading to acetate, which is then in part converted to cholesterol. This clinical trial conducted by Winitz and his collaborators strongly supports the conclusion reached by Yudkin that sugar (sucrose) is dangerous as well as sweet. The ordinary diet, with 20 percent of the food energy from sucrose, corresponds to an average intake of 125 g per day, 100 pounds per year. To cut this intake in half greatly improves the health, decreasing the chance of developing heart disease and other diseases, lowering the blood cholesterol, and strengthening the body’s natural defense mechanisms.
You can decrease your intake of sucrose by half very easily by developing some good habits. 1. Keep away from the sugar bowl. Do not add sugar to your tea or coffee. A rounded teaspoonful of sugar weighs 9 g. Each time that you refrain from adding it to your cup of coffee or tea you decrease your intake of sucrose by that amount. 2. Do not eat prepared breakfast cereals (frosted cereals) with added sugar. Some of these cereals are 50 percent sugar. When you eat a 2-ounce serving you eat 28 g of sucrose. Eat sugar-free cereals, and add only a small amount of sugar. 3. Do not eat sweet desserts regularly. As Yudkin has pointed out, this does not mean that when you are a guest you should refuse to eat the dessert your hostess has prepared. 4. Do not drink soft drinks (carbonated beverages), except club soda (car bonated water). The usual 6-ounce bottle or can of a cola drink con tains 17 g of sucrose. If you were to drink four of them per day and eat the ordinary American diet, your sucrose intake would be 155 pounds per year, and, according to Yudkin, you would be fifteen times as likely to die of heart disease at an early age as if you restricted your intake to 50 pounds per year by following these rules. A glass of ginger ale contains 14 g of sucrose, a glass of cream soda 17 g, a glass of fruit-flavored soda (citrus, cherry, grape, strawberry, Tom Col lins mix, other) 20 g, a glass of root beer 18 g, a glass of tonic water (quinine water) 14 g. I do not recommend the diet sodas, in which the sucrose is replaced by artificial sweeteners, because I am worried about the possible toxicity of these nonorthomolecular substances. The soft drink that I recommend for every person except those on a low-sodium diet is club soda, which contains no sucrose. I also recommend water. If you keep your intake of sugar down, vitamin C can supply the rest of your insurance against high cholesterol concentration in your bloodstream. As I explain in Chapter 18, where we return to the subject of heart disease, vitamin C is involved in the biochemistry of the synthesis and destruction of cholesterol in our bodies.
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S c u rv y , b e r ib e r i, p e lla g r a , p e r n ic io u s a n e m ia , a n d ric k e ts a r e d is e a s e s th a t o v e r p a s t m ille n n ia c a u s e d a tr e m e n d o u s a m o u n t o f s u ffe rin g a n d m illio n s o f d e a t h s . W e k n o w t o d a y t h a t e a c h o f t h e s e d i s e a s e s is t h e r e s u l t o f a d e fic ie n c y in th e a m o u n t o f a n i m p o r t a n t k in d o f m o le c u le in th e o r g a n s a n d tis s u e s o f th e b o d y . S c u rv y r e s u lts fro m a n in s u ffic ie n t s u p p ly o f v ita m in C ; b e r ib e r i, fro m a n in s u ffic ie n t s u p p ly o f v ita m in B , ( th ia m in e ) ; p e l la g ra , fro m a n in s u ffic ie n t s u p p ly o f v ita m in B 3 ( n ia c in ). P e rn ic io u s a n e m ia r e s u l t s f r o m a n i n s u f f i c i e n t a m o u n t o f v i t a m i n B 12 ( c o b a l a m i n ) i n t h e b l o o d , c a u s e d b y th e f a ilu r e o f th e p a tie n t to s y n th e s iz e a s u b s ta n c e th a t c a r r ie s th e v i t a m i n a c r o s s t h e i n t e s t i n a l w a l l . R i c k e t s ( d e f e c t i v e b o n e g r o w t h ) is c a u s e d b y a l a c k o f v i t a m i n D i n t h e d i e t o r b y i n s u f f i c i e n t e x p o s u r e o f t h e s k i n to s u n lig h t. T h is k n o w le d g e , w h ic h h a s b e e n o b ta in e d o n ly d u r in g th e la s t o n e h u n d r e d y e a r s , h a s le d to n e a r ly c o m p le te c o n tr o l o f th e d is e a s e s in th e d e v e lo p e d c o u n tr ie s a n d to g r e a t im p r o v e m e n t in th e g e n e r a l h e a lth o f t h e ir p o p u la tio n s .
Scurvy has been known for centuries, but it was not until 1911 that its cause was clearly recognized to be a dietary deficiency. Until the 1880s the disease was common among sailors on board ships taking long voyages. It also frequently broke out among soldiers in an army on campaign, in com munities in times of scarcity of food, in cities under siege, and in prisons
and workhouses. Scurvy plagued the California gold miners 140 years ago and the Alaskan gold miners 90 years ago. The onset of scurvy is marked by a failure of strength, by depression, restlessness, and rapid exhaustion on making an effort. The skin becomes sallow or dusky. The patient complains of pain in the muscles. He is mentally depressed. Later his face looks haggard. His gums ulcerate, his teeth drop out, and his breath is fetid. Hemorrhages of large size penetrate the muscles and other tissues, giving him the appearance of being exten sively bruised. The later stages of the disease are marked by profound exhaustion, diarrhea, and pulmonary and kidney troubles, leading to death. The ravages of scurvy among the early sea voyagers were terrible. On a long voyage the sailors lived largely on biscuits, salt beef, and salt pork, which contain very little vitamin C. Between 9 July 1497 and 30 May 1498 the Portuguese navigator Vasco da Gama made the voyage of discov ery of the sea route around Africa to India, sailing from Lisbon to Calicut. During this voyage 100 of his crew of 160 died of scurvy. In the year 1577 a Spanish galleon was found adrift in the Sargasso Sea, with everyone on board dead of scurvy. Late in 1740 the British admiral George Anson set out with a squadron of six ships manned by 961 sailors. By June 1741, when he reached the island of Juan Fernandez, the number of sailors had decreased to 335, more than half of his men having died of scurvy. The conqueror of Mexico, Hernando Cortes, discovered Baja California in 1536 but had to turn back before discovering California itself because his sailors were dying of scurvy. The idea that scurvy could be prevented by a proper diet developed only slowly. In 1536 the French explorer Jacques Cartier discovered the St. Lawrence River and sailed upstream to the site of the present city of Quebec, where he and his men spent the winter. Twenty-five of the men died of scurvy, and many others were very sick. A friendly Indian advised them to drink tea made of the leaves and bark of the arbor vitae tree, Thuja occidentalis. The treatment was beneficial. The leaves or needles of this tree were later shown to contain about 50 milligrams of vitamin C per 100 grams. The sixteenth-century English admiral Sir John Hawkins found that on a very long voyage the crew suffered from scurvy in proportion to the length of time they were restricted to dry foods. They recovered rapidly as soon as they had access to a supply of succulent plants, including citrus fruits. Since fresh fruits and vegetables are obviously the most difficult of all supplies to maintain on shipboard, efforts were made to find a substitute capable of marine transport. In 1747, while in the British naval service, the Scottish physician James Lind carried out a now-famous experiment with twelve patients severely ill
with scurvy. He placed them all on the same diet, except for one item, one or another of the reputed remedies that he was testing. To each of two patients he gave two oranges and one lemon per day; to two others, cider; to the others, dilute sulfuric acid, or vinegar, or sea water, or a mixture of drugs. At the end of six days the two who had received the citrus fruits were well, whereas the other ten remained ill. Lind carried out further studies, which he later described in his book A Treatise on Scurvy (1753). The experiences of the great English explorer Captain James Cook in controlling scurvy are particularly striking. Cook was the son of a day laborer on a farm in Yorkshire. As a boy he showed unusual ability, and at eighteen he was apprenticed to a ship owner, who encouraged him in his study of mathematics and navigation. After he joined the navy he advanced rapidly and became one of the world’s greatest explorers. The story of his dealing with scurvy among his crews on his Pacific voyages during the period 1768 to 1780 has been told by Kodicek and Young in Notes and Records of the Royal Society of London (1969). These authors quote the following song by the sailor T. Perry, a member of the crew of Cook’s flagship H.M.S. Resolution: We were all hearty seamen, no colds did we fear And we have from all sickness entirely kept clear Thanks be to the Captain, he has proved so good Amongst all the Islands to give us fresh food. This song, written two hundred years ago, indicates that Cook’s sailors believed that something in the fresh food provided them with protection against colds, as well as against other diseases. Captain Cook made use of many antiscorbutic agents. Whenever the ships reached shore he ordered the sailors to gather fruits, vegetables, ber ries, and green plants. In South America, Australia, and Alaska the leaves of spruce trees were gathered and made into an infusion called spruce beer. Nettletops and wild leeks were boiled with wheat and served at breakfast. Cook began one voyage with a supply of 7,860 pounds of sauerkraut, enough to provide 2 pounds per week for a period of a year for each of the seventy men on board his first flagship, the Endeavour. (Saukerkraut con tains a good amount of vitamin C, about 30 milligrams [mg] per 100 grams.) The result of his care was that, despite some illness, not a single member of his crew died of scurvy during his three Pacific voyages, carried out at a time when scurvy was still ravaging the crews of most vessels on such protracted expeditions. Cook’s scientific contributions were recognized by his election as a Fellow of the Royal Society of London, which awarded him the Copley Medal for his work on the prevention of scurvy.
Although the most intelligent travelers since the time of Hawkins had expressed their opinion that the juice of citrus fruits—principally oranges, lemons, and limes—was a good substitute for fresh fruit and vegetables in preventing scurvy, acceptance by the public was slow. Such juice was ex pensive and troublesome to carry, so skippers and ship owners found it expedient to be skeptical. In the controversy some attempts to find a solu tion involved using orange, lemon, and lime juice that had been boiled down to a syrup. But they were unsuccessful. We know today that most of the ascorbic acid in the juice was destroyed by this process. Controversy over the value of fresh citrus juice continued. Finally, however, in 1795, forty-eight years after Lind had carried out his striking experiment, the British Admiralty ordered that a daily ration of fresh lime juice (not boiled to a syrup) be given to the sailors. Scurvy soon disappeared from the British Navy. From this salutary practice the British sailor came to be known as a “Lime-juicer,” or “Limey.” The spirit of free enterprise remained dominant in the British Board of Trade, however, and scurvy continued to ravage the British merchant ma rine for seventy years longer. Not until 1865 did the Board of Trade pass a similar lime-juice regulation for the merchant marine. At the present time scurvy, complicated by other deficiency diseases, is found in populations that are ravaged by starvation and severe malnutri tion, usually as a result of poverty. In the United States scurvy is also occasionally observed in people who are not poverty-striken: among infants six to eighteen months old who are fed a formula without vitamin supple ment and such persons as middle-aged or elderly bachelors or widowers who for convenience and through ignorance ingest a diet deficient in the essential nutrients. E. Gheraskin, W. M. Ringsdorf, Jr., and E. L. Sisley in their book The Vitamin C Connection (1983) recount the story of a forty-eight-year-old woman in California who came to the hospital because of pain, indigestion, and swelling of the abdomen. Over a period of four years she had six surgical operations. Each time the abdomen was found to be full of blood. In the effort to prevent the recurrent bleeding, her ovaries, uterus, appen dix, spleen, and part of the small intestine were removed. Finally, after four years, a doctor asked her what she ate and found that her diet con tained essentially no fruits or vegetables and that she took no supplemen tary vitamins. She was getting a little vitamin G in her food, enough to keep her from dying of scurvy but not enough to keep her blood vessels strong enough to prevent internal bleeding. Her blood level of vitamin G was only 0.06 mg per deciliter. When she was put on 1000 mg of vitamin C per day she regained normal health, qualified, however, by the surgery she had endured (Cook and Milligan, 1977).
Not many people in the United States develop this sort of incipient scurvy. I believe, however, for reasons discussed throughout this book, that most of the American people suffer from a mild or even rather serious prescorbutic condition and also from deficiencies in other essential nutri ents. The regular intake of supplements of vitamin C and other vitamins and minerals, in addition to a good diet and other health practices, can lead to a better life for almost every person. The article on scurvy in the eleventh edition of the Encyclopedia Britannica (1911) states that the incidence of scurvy depends upon the nature of the food and that it is disputed whether the cause is the absence of certain constituents in the food or the presence of some actual poison. The study of another vitamin-deficiency disease, beriberi, was then in a similar state. Beriberi was prevalent in eastern Asia, where rice is the staple food, and also in the Pacific islands and South America. It involves paralysis and numbness, starting from the legs and leading to cardiac and respiratory disorders and to death. In the Dutch East Indies, about one hundred years ago, soldiers, sailors, prisoners, mine workers, plantation workers, and persons admitted to a hospital for minor ailments were dying of the disease by the thousands. Young men in seemingly good health some times died suddenly, in terrible distress through inability to breathe. In 1886 a young Dutch physician, Christiaan Eijkman, was asked by the Dutch government to study the disease. For three years he made little progress. Then he noticed that the chickens in the laboratory chickenhouse were dying of a paralytic disease closely resembling beriberi. His studies of the chickens’ disease were suddenly brought to an end, when the chickens that had not yet died recovered and no new cases developed. He found, on investigating the circumstances, that the man in charge of the chickens had been feeding them, from 17 June to 27 November, on polished rice (with the husks removed) prepared in the military hospital kitchen for the hospi tal patients. Then a new cook took charge of the kitchen; he refused, as Eijkman was to report in his address accepting the Nobel Prize for physiol ogy and medicine in 1929, to “allow military rice to be taken for civilian chickens.” The disease had broken out among the chickens on 10 July and disappeared during the last days of November. It was immediately confirmed that a diet of polished rice causes death of chickens in three or four weeks, whereas they remain in good health when fed unpolished rice. A study of 300,000 prisoners in 101 prisons in the Dutch East Indies was then made, and it was found that the incidence of beriberi was three hundred times as great in the prisons where polished rice was used as a staple diet as in those where unpolished rice was used. Eijkman found that he could isolate an extract from the bran of the rice that had protective power against beriberi. At first he had thought that
some substance in the bran acted as an antidote for a toxin assumed to be present in polished rice, but by 1907 he and his collaborator, Gerrit Grijns, had concluded that the bran contains a nutrient substance that is required for good health. In the meantime a number of investigators had been studying the nutri tional value of foods. It was shown that for good health certain minerals are needed (compounds of sodium, potassium, iron, copper, and other metals), as well as proteins, carbohydrates, and fats. The Swiss biochemist Lunin found in 1881 that mice died when they were fed a mixture of purified protein, carbohydrate, fat, and minerals, whereas those fed the same diet with the addition of some milk survived. He concluded that “a natural food such as milk must therefore contain besides these known principal ingredi ents small quantities of unknown substances essential to life.” Similar ob servations were made in the same laboratory (in Basel) ten years later by another Swiss biochemist, Socin, who found that small amounts of either egg yolk or milk, in addition to the purified diet, sufficed to keep the mice in good health. In 1905 the Dutch physiologist Pekelharing found that very small amounts of the unknown essential substances in milk were enough to keep the animals in good health. Between 1905 and 1912 the English biochemist F. Gowland Hopkins carried on similar studies with rats. His results were announced in 1911 and published in detail in 1912. Hopkins shared the 1929 Nobel Prize with Eijkman. In 1911 Casimir Funk, a Polish biochemist then working in the Lister Institute in London, published his theory of “vitamins,” based upon his review of the existing knowledge about diseases associated with faulty nu trition. He suggested that four such substances are present in natural foods and that they serve to provide protection against four diseases—beriberi, scurvy, pellagra, and rickets. Funk coined the word vitamine from the Latin word vita (“life”) and the chemical term amine, a member of a class of compounds of nitrogen, which includes, of course, the amino acids. Later, when it was found that some of these essential substances do not contain nitrogen, the word was changed to vitamin. In the meantime the American investigator E. V. McCollum had been studying nutritional factors at the University of Wisconsin. He and his coworkers reported in 1913 the need for two “necessary” food factors, one soluble in fats and one in water. In 1915 he named them “fat-soluble A” and “water-soluble B.” This was the start of the modern nomenclature of the vitamins. The vitamin that prevents scurvy was then named watersoluble C, and the one that prevents rickets was named fat-soluble D. When “water-soluble B” was found to contain not only the protective agent against beriberi but also several others, they were given the names Bl5 B2, and so on to B17. Some of these substances have been found not to be
vitamins, their requirement for life and health being uncertain, but the names B,, B2, B3, B6, and B12 are still used. During the following years a number of efforts were made to isolate pure vitamin C from lemon juice and other foods. The pure vitamin was finally obtained in 1928, by Albert Szent-Gyorgyi. He was working on another problem and at first did not know that his new substance was vitamin C. He named the substance hexuronic acid. Szent-Gyorgyi was given the Nobel Prize for physiology and medicine for 1937 in recognition of his dis coveries concerning the biological oxidation processes, with especial refer ence to vitamin C and to the role of fumaric acid in these processes. Szent-Gyorgyi was born in Budapest in 1893. He studied medicine in Budapest and immediately began his career as an investigator in the fields of physiology and biochemistry. While he was working in the Netherlands in 1922 he began a study of the oxidation reactions that cause a brown pigmentation to appear in certain fruits, such as apples and bananas, as they decay. In the course of these studies he found that cabbages contain a reducing agent (an agent that can combine with oxygen) that prevents the formation of the brown pigment, and that the adrenal glands of animals contain the same reducing agent or a similar one. Because of his interest in physiological oxidation-reduction reactions he began to try to isolate this reducing agent from the plant tissues and from adrenal glands. In 1927 Szent-Gyorgyi received a fellowship from the Rockefeller Foun dation, permitting him to spend a year in the laboratory of F. Gowland Hopkins in Cambridge, England. Here he succeeded in isolating the sub stance from plant tissues and from the adrenal glands of animals. He then spent a year at the Mayo Clinic, Rochester, Minnesota, where he suc ceeded in obtaining 25 grams (g) of the substance, which he had called hexuronic acid. In 1930 he returned to Hungary, where he found that Hungarian paprika contains large amounts of the substance. He and his collaborators, and also the American investigators Waugh and King, showed in 1932 that Szent-Gyorgyi’s substance was vitamin C. SzentGyorgyi himself had found that the chemical formula of the substance is C6H80 6. He gave some of the crystalline material to the English sugar chemist W. M. Haworth, who determined its structural formula, establish ing the atom-to-atom connections in the molecule (to be discussed in more detail in Chapter 9). Szent-Gyorgyi and Haworth then changed its name to ascorbic acid, meaning the acidic substance that prevents and cures scurvy. Haworth demonstrated also the two chemical reactions by which the sugar dextrose or glucose, a carbohydrate with the formula C(lH 120 6, is made to give up four hydrogen atoms to be transformed to C6HK0 6, with two molecules of water as byproduct. Essentially the same reactions are conducted by the living cells that manufacture vitamin C and by the chemi-
cal reactors that make the identical “synthetic” vitamin G. The very sim plicity of the molecule and its manufacture from glucose, the principal fuel sustaining life in tissue cells, suggest the importance of vitamin C and explain its ubiquity in the tissues of the body. Two twentieth-century American chemists, Robert R. Williams and Roger J. Williams, have made important contributions to our knowledge about the B vitamins. Their parents were missionaries, and they were born in India. R. R. Williams worked for many years as director of chemical research for Bell Telephone Laboratories in New York City on problems such as improving the electrical insulation on submarine cables. He set up a laboratory in his home and devoted his spare time to trying to isolate the substance in rice hulls that protects against beriberi. After years of work he and his collaborators, R. R. Waterman (his son-in-law) and E. R. Buchman, succeeded in isolating the substance, which they named thia mine, in determining its chemical constitution, and in devising ways of synthesizing it, making it available at a low price for improving the health of people all over the world. R. J. Williams, when he was professor of chemistry at Oregon State University in 1933, discovered another B vitamin, which he named panto thenic acid. Later, at the University of Texas, he studied a factor in extracts from yeast and liver that had been reported in 1931 and 1938 by other investigators to be effective in controlling anemia in animals. In 1941 he and his students had decided that it was a vitamin, which they named folic acid. In 1916 the American physician J. Goldberger reported that the disease pellagra, which was causing great suffering and many deaths among the poor people in the southern United States, could be prevented by improved nutrition (milk and eggs) and in no other way. Then in 1937 the American biochemist C. A. Elvehjem and his students at the University of Wisconsin showed that niacin or niacinamide cured a similar disease, blacktongue, in dogs, and in the same year these substances, vitamin B3, were shown to cure pellagra in human beings. There are interesting stories that might be recounted about the other vitamins. For example, after some red crystals of a cobalt compound that has an astounding protective effect against pernicious anemia had been isolated, the greatest organic chemists in the world were unable to deter mine the chemical constitution of the substance. Today called vitamin B12, it is a complex molecule containing 183 atoms of carbon, hydrogen, nitro gen, oxygen, phosphorus, and cobalt. Its structure was ultimately resolved by an X-ray crystallographer, Dorothy Hodgkin, at Oxford University. For this work she was given the Nobel prize for chemistry in 1964. While there is more to tell about the history of how vitamins were discovered, let us turn now to their role in the physiology of good health.
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We are accustomed to thinking of human beings as the highest of all species of living organisms. In one sense they are: They have achieved effective control over a large part of the earth and have even begun to extend their realm as far as the moon and Mars. But in their biochemical capabilities they are inferior to many other organisms, including even unicellular orga nisms, such as bacteria, yeasts, and molds. The red bread mold (.Neurosporo), for example, is able to carry out in its cells a great many chemical reactions that human beings are unable to carry out. The red bread mold can live on a very simple medium, consisting of water, inorganic salts, an inorganic source of nitrogen, such as ammo nium nitrate, a suitable source of carbon, such as sucrose, and a single vitamin, biotin. All other substances required by the red bread mold are synthesized by it, using its internal biochemical mechanisms. The red bread mold does not need to have any amino acids in its diet, because it is able to synthesize all of them and also to synthesize all of the vitamins except biotin. The red bread mold owes its survival, over hundreds of millions of years, to its great biochemical capabilities. If, like humans, it were unable to synthesize the various amino acids and vitamins, it would not have sur vived, because it could not have solved the problem of obtaining an ade quate diet.
From time to time a gene in the red bread mold undergoes a mutation, such as to cause the cell to lose the ability to manufacture one of the amino acids or vitaminlike substances essential to its life. This mutated spore gives rise to a deficient strain of red bread mold, which could stay healthy only with an addition to the diet that suffices for the original type of the mold. The scientists G. W. Beadle and E. L. Tatum carried on extensive studies of mutated strains of the red bread mold, when they were working in Stanford University, beginning about 1938. They were able to keep the mutant strains alive in the laboratory by providing each strain with the additional food that it needed for good health, as shown by a normal rate of growth. It was mentioned in Chapter 7 that the substance thiamine (vitamin Bl) is needed by human beings to keep them from dying of beriberi, and that chickens fed on a diet that contains none of this food also die of a neurologi cal disease resembling beriberi. It has been found, in fact, that thiamine is needed as an essential food for all other animal species that have been studied, including the domestic pigeon, the laboratory rat, the guinea pig, the pig, the cow, the domestic cat, and the monkey. We may surmise that the need of all of these animal species for thiamine as an essential food, which they must ingest in order not to develop a disease resembling beriberi in human beings, resulted from an event that took place more than five hundred million years ago. Let us consider the epoch, early in the history of life on earth, when the early animal species from which present-day birds and mammals have evolved populated a part of the earth. We assume that the animals of this species nourished themselves by eating plants, possibly together with other food. All plants contain thiamine. Accordingly the animals would have in their bodies the thiamine that they had ingested with the foodstuffs that they had eaten, as well as the thiamine that they themselves synthesized by use of their own synthetic mechanism. Now let us assume that a mutant animal appeared in the population, an animal that, as the result of the impact of a cosmic ray on a gene or of the action of some other mutagenic agent, had lost the biochemical machinery that still permitted the other members of the species to manufacture thiamine from other substances. The amount of thiamine provided by the ingestion of food would suffice to keep the mutant well nourished, essentially as well nourished as the un mutated animals. The mutant would have an advantage over the unmutated animals, in that it would be liberated from the burden of the machinery for manufacturing its own thiamine. As a result, the mutant would be able to have more offspring than the other animals in the population. By reproduc tion the mutated animal would pass its advantageously mutated gene along to some of its offspring, and they too would have more than the average number of offspring. Thus in the course of time this advantage, the advan-
tage of not having to do the work of manufacturing thiamine or to carry within itself the machinery for this manufacture, could permit the mutant type to replace the original type. To recapitulate: Many different kinds of molecules must be present in the body of an animal in order that the animal be in good health. Some of these molecules can be synthesized by the animal; others must be ingested as foods. If the substance is available as a food, it is advantageous to the animal species to rid itself of the burden of the machinery for synthesiz ing it. It is believed that, over the millennia, the ancestors of human beings were enabled, over and over again, by the availability of certain substances as foods, including the essential amino acids and the vitamins, to simplify their own biochemical lives by shuffling off the machinery that their ances tors had needed for synthesizing these substances. Evolutionary processes of this sort gradually, over millions of years, led to the appearance of new spe cies, including man. Some interesting experiments concern competition between strains of or ganisms that require a certain substance as food and those that do not require the substance, because they have the ability to synthesize it them selves. These experiments were carried out at the University of California, Los Angeles, by Zamenhof and Eichhorn, who published their findings in 1967. They studied a bacterium, Bacillus subtilis3 by comparing a strain that had the power of manufacturing the amino acid tryptophan and a mutant strain that had lost the ability to manufacture it. If the same num bers of cells of the two strains were put in a medium that did not contain any tryptophan the strain that could manufacture tryptophan survived, whereas the other strain died out. If, however, some cells of the two strains were put together in a medium containing a good supply of tryptophan, the scales were turned. The mutant strain, which had lost the ability to manu facture the amino acid, survived, and the original strain, with the ability to manufacture the amino acid, died out. The two strains of bacteria differed only in a single mutation, the loss of the ability to manufacture tryptophan. We are hence led to conclude that the burden of using the machinery for tryptophan synthesis was disadvantageous to the strain possessing this abil ity and hampered it, in its competition with the mutant strain, to such an extent as to cause it to fail in this competition. The number of generations (cell divisions) required for takeover in this series of experiments (starting with an equal number of cells, to a million times as many cells of the victorious strain) was about fifty, which would correspond to only about fifteen hundred years for humans (thirty years per generation). We may say that Zamenhof and Eichhorn carried out a small-scale experiment about the process of the evolution of species. This experiment, and several others that they also carried out, showed that it can be advanta
geous to be free of the internal machinery for synthesizing a vital substance, if the vital substance can be obtained instead as a food from the immediate environment. Most of the vitamins required by humans for good health are also re quired by animals of other species. Vitamin A is an essential nutrient for all vertebrates for vision, maintenance of skin tissue, and normal develop ment of bones. Riboflavin (vitamin B2), pantothenic acid, pyridoxine (vita min B6), nicotinic acid (niacin), and cyanocobalamin (vitamin B12) are re quired for good health by the cow, pig, rat, chicken, and other animals. It is likely that the loss of the ability to synthesize these essential substances, like the loss of the ability to synthesize thiamine, occurred rather early in the history of animal life on earth, when the primitive animals began living largely on plants, which contain a supply of these nutrients. Irwin Stone pointed out in 1965 that, whereas most species of animals can synthesize ascorbic acid, humans and other primates that have been tested, including the rhesus monkey, the Formosan long-tail monkey, and the ringtail or brown capuchin monkey, are unable to synthesize the sub stance and require it as a supplementary vitamin. He concluded that the loss of the ability to synthesize ascorbic acid probably occurred in the com mon ancestor of the primates. A rough estimate of the time at which this mutational change occurred is twenty-five million years ago (Zuckerkandl and Pauling, 1962). The guinea pig and an Indian fruit-eating bat are the only other mammals known to require ascorbic acid as a vitamin. The red-vented bulbul and some other Indian birds (of the order Passeriformes) also re quire ascorbic acid. The overwhelming majority of mammals, birds, am phibians, and reptiles have the ability to synthesize the substance in their tissues, usually in the liver or the kidney. The loss of the ability by the guinea pig, the fruit-eating bat, the red-vented bulbul, and other passeriform birds probably resulted from independent mutations in populations of these species of animals living in an environment that provided an ample supply of ascorbic acid in the available foodstuffs. We may ask why ascorbic acid is not required as a vitamin in the food of the cow, pig, horse, rat, chicken, and many other species of animals that do require the other vitamins needed by humans. Ascorbic acid is present in green plants, along with these other vitamins. When green plants became the steady diet of the common ancestor of humans and other mammals, hundreds of millions of years ago, why did not this ancestor undergo the mutation of eliminating the mechanism for synthesizing ascorbic acid, as well as those for synthesizing thiamine, pantothenic acid, pyridoxine, and other vitamins? I think the answer is that for optimum health more ascorbic acid was needed that could be provided under ordinary conditions by the usually
available green plants. Part of the extra amount is needed by animals because ascorbic acid is required for the synthesis of collagen, as will be explained in Chapter 9. This protein is present in large amounts in the bodies of animals but not in plants. Let us consider the common precursor of the primates, at a time about twenty-five million years ago. This animal and his ancestors had for hun dreds of millions of years continued to synthesize ascorbic acid from the glucose in the foods that they had ingested. Let us assume that a population of this species of animals was living, at that time, in an area that provided an ample supply of food with an unusually large content of ascorbic acid, permitting the animals to obtain from their diet approximately the amount of ascorbic acid needed for optimum health. A cosmic ray or some other mutagenic agent then caused a mutation to occur, such that the enyzme in the liver that catalyzes the conversion of L-gulonolactone to ascorbic acid was no longer present in the liver. Some of the progeny of this mutant animal would have inherited the loss of the ability to synthesize ascorbic acid. These mutant animals would, in the environment that provided an ample supply of ascorbic acid, have an advantage over the ascorbic-acidproducing animals, in that the mutants had been relieved of the burden of constructing and operating the machinery for producing ascorbic acid. Un der these conditions the mutant would gradually replace the earlier strain. A mutation that involves the loss of the ability to synthesize an enzyme occurs often. Such a mutation requires only that the gene be damaged in some way or be deleted. (The reverse mutation, leading to the ability to produce the enzyme, is difficult, and would occur only extremely rarely.) Once the ability to synthesize ascorbic acid has been lost by a species of animals, that species depends for its existence on the availability of ascorbic acid as a food. The fact that most species of animals have not lost the ability to manu facture their own ascorbic acid shows that the supply of ascorbic acid avail able generally in foodstuffs is not sufficient to provide the optimum amount of this substance. Only in an unusual environment, in which the available food provided unusually large amounts of ascorbic acid, have circumstances permitted a species of animal to abandon its own powers of synthesis of this important substance. These unusual circumstances occurred for the precur sor of humans and other primates, for the guinea pig, for the Indian fruit eating bat, and for the precursor of the red-vented bulbul and some other species of passeriform birds, but they have not occurred, through the hun dreds of millions of years of evolution, for the precursors of most other animals. Thus the consideration of evolutionary processes, as presented in the foregoing analysis, indicates that the ordinarily available foodstuffs might well provide nearly the optimum amounts of thiamine, riboflavin, niacin, vitamin A, and other vitamins that are required as essential nutri
ents by all mammalian species, but be deficient in ascorbic acid. For this food, essential for humans but synthesized by many other species of ani mals, the optimum rate of intake is indicated to be larger than the rate associated with the ingestion of the ordinarily available diet. Thus, while the loss of the capacity to synthesize vitamin C conferred some evolutionary advantage on the primates and other lines, this genetic deletion also exposed them to some risk. Dr. Claus W. Jungeblut, a pioneer as early as the 1930’s on the use of vitamin C for the therapy of infectious disease, advanced an interesting argument, new to me, in a letter to me on 10 February 1971: “. . . One might even go a step further here by asking why the guinea pig, of all common laboratory animals, shares with man certain physiological characteristics that include susceptibility not only to scurvy but also to anaphylactic shock, diphtheritic intoxication, pulmonary tuberculosis, a poliomyelitis-like neurotropic virus infection, and last but not least a form of viral leukemia that is indistinguishable from its human counterpart. None of the vitamin-C-synthesizing laboratory animals (rab bits, mice, rats, hamsters, etc.) answer positively to this call.” I have checked the amounts of various vitamins present in 110 raw, natural plant foods, as given in the tables in the metabolism handbook published by the Federation of American Societies for Experimental Biol ogy (Altman and Dittmer, 1968). When the amounts of vitamins corre sponding to one day’s food for an adult (the amount that provides 2500 kilocalories [kcal] of energy) are calculated, it is found that for most vita mins this amount is about three times the daily allowance recommended by the Food and Nutrition Board. For ascorbic acid, however, the average amount in the daily ration of the 110 plant foodstuffs is 2.3 grams (g), about forty times the amount recommended as the daily allowance for a person with a caloric requirement of 2500 kcal per day (see table on fac ing page). It is almost certain that some evolutionarily effective mutations have occurred in humans and their immediate predecessors rather recently (within the last few million years) such as to permit life to continue on an intake of ascorbic acid less than that provided by raw plant foods containing a high content of ascorbic acid. These mutations might involve an increased ability of the kidney tubules to pump ascorbic acid back into the blood from the glomerular filtrate (dilute urine, being concentrated on passage through the tubules) and an increased ability of certain cells to extract ascorbic acid from the blood plasma. The adrenal glands have been found to be richly supplied with ascorbic acid, extracting it from the blood and employing it in the synthesis of adrenalin, the all-important mobilizer of the body in response to stress; the supply of ascorbic acid in the adrenals may be avail able to the rest of the body by return to the bloodstream when the supply
Water-soluble content (mg) of 110 raw natural plant foods (referred to amount giving 2500 kcal of food energy).
Nuts and grains (11) Fruit, low-C (21) Beans and peas (15) Berries, low-C (8) Vegetables, low-C (25) Average for 110 foods Intermediate-G foods (16) Collards Chives Cabbage Brussels sprouts Cauliflower Mustard greens Kale Broccoli spears Black currants Parsley Hot red chili peppers Sweet green peppers Hot green chili peppers Sweet red peppers
Thiamine
Riboflavin
Nicotinic acid
Ascorbic acid
3.2 1.9 7.5 1.7 5.0 5.0 7.8 10.8 7.1 6.2 5.6 10.0 8.9
1.5 2.0 4.7 2.0 5.9 5.4 9.8 17 11.6 5.0 8.9 9.3 18
27 19 34 15 39 41 77 92 45 32 50 65 65
7.8 2.3 6.8 3.8 9.1 6.1 6.5
18 2.3 15 7.7 9.1 4.1 6.5
70 14 68 112 57 115 40
0 600 1000 1200 1200 2300 3400 5000 5000 5100 5700 7200 7800 8200 8800 9300 9800 14200 14600 15900 16500
Nuts and grains: almonds, filberts, macadamia nuts, peanuts, barley, brown rice, whole grain rice, sesame seeds, sunflower seeds, wild rice, wheat. Fruit (low in vitamin C, less than 2500 mg): apples, apricots, avocados, bananas, cherries (sour red, sweet), coconut, dates, figs, grapefruit, grapes, kumquats, mangoes, nectarines, peaches, pears, pineapple, plums, crabapples, honeydew melon, watermelon. Beans and peas: broad peas (immature seeds, mature seeds), cowpeas (immature seeds, mature seeds), lima beans (immature seeds, mature seeds), mung beans (seeds, sprouts), peas (edible pod, green mature seeds), snapbeans (green, yellow), soybeans (immature seeds, mature seeds, sprouts). Berries (low-C, less than 2500 mg): blackberries, blueberries, cranberries, loganberries, raspberries, currants, gooseberries, tangerines. Vegetables (low-C, less than 2500 mg): bamboo shoots, beets, carrots, celeriac root, celery, corn, cucumber, dandelion greens, eggplant, garlic cloves, horseradish, lettuce, okra, onions (young, mature), parsnips, potatoes, pumpkins, rhubarb, rutabagas, squash (summer, winter), sweet potatoes, green tomatoes, yams. Intermediate-C foods (2500-4900 mg): artichokes, asparagus, beet greens, cantaloupe, chicory greens, Chinese cabbage, fennel, lemons, limes, oranges, radishes, spinach, zucchini, strawberries, swiss chard, ripe tomatoes.
from nutrition runs low. On general principles we can conclude, however, that these mechanisms require energy and are a burden to the organism. The optimum rate of intake of ascorbic acid might still be within the range given above, 2.3 g per day or more, or might be somewhat less; and, of course, there is always the factor of biochemical individuality, discussed in Chapter 10.
It is not unreasonable to think that over the last millions of years the human body has adjusted somewhat to the food that was available and was eaten, so that the amounts of various nutrients in the food might be an indication of the optimum intakes of these nutrients. During the past few years paleontologists, anthropologists, and other scientists have obtained a great amount of information about the foods eaten by primitive human beings during the period from forty thousand years ago to the development of agriculture ten thousand years ago. Studies have also been made of the few hunter-gatherer societies that have survived until recently or until the present time. A review of the subject of paleolithic nutrition was published in 1985 by Dr. S. Boyd Eaton and Dr. Melvin Konner of the School of Medicine and the Department of Anthropology of Emory University, At lanta, Georgia. This article has provided much of the basis for the follow ing paragraphs. Five million years ago fruits and other vegetable foods were the main dietary constituents of the primates. It was about then that the lines leading to present-day humans and apes diverged. The ancestors of human beings began eating increasing amounts of meat. Modern man (Homo sapiens) developed about forty-five thousand years ago. His diet was about 50 per cent vegetable material and 50 percent meat, including fish, shellfish, small animals, and large animals. As agriculture developed, about ten thousand years ago, which greatly increased the use of grains as food, the amount of vegetables in the diet became as great as 90 percent, with a drastic decline in the amount of meat. European humans thirty thousand years ago, with a high intake of meat, were about 6 inches taller than their descendants after the development of agriculture. Eaton and Konner state that “The same pattern was repeated later in the New World: the Paleo-indians were big-game hunters 10,000 years ago, but their descendants, in the period just before European con tact, practiced intensive food production, ate little meat, were considerably shorter, and had skeletal manifestations of suboptimal nutrition, which apparently reflect both the direct effects of protein-calorie deficiency and the synergistic interaction between malnutrition and infection. Since the Industrial Revolution, the animal-protein content of Western diets has be come more nearly adequate, as indicated by increased average height: we are now nearly as tall as were the first biologically modern human beings. However, our diets still differ markedly from theirs, and these differences lie at the heart of what has been termed ‘affluent malnutrition’.” Eaton and Konner point out that the quality of modern meat is different from that of Paleolithic meat. Domesticated animals are fatter than wild animals. Meat now often contains 25 to 30 percent fat, whereas game
contains only about 4 percent fat. The vegetable foods are also different. Hunter-gatherers eat roots, beans, nuts, tubers, fruits, flowers, and edible gums but only small amounts of cereal grains, such as wheat, oats, and rice, which constitute a large part of our modern diet. Eaton and Konner point out that the late Paleolithic diet compares with the present American average diet in the following ways: more protein, less fat; the same amount of carbohydrate (but more starch, less sucrose); the same amount of cholesterol (about 600 milligrams [mg] per day); more fiber (36 g vs. 20 g per day); much less sodium; more potassium and more calcium; much more vitamin C (400 mg per day vs. 88 mg per day). They conclude that “The diet of our remote ancestors may be a reference stan dard for modern human nutrition and a model for defense against certain ‘diseases of civilization.’”
9.V
it a m
i n s
in
th e
B o d y
It was the vitamin-deficiency diseases, as we saw in Chapter 7, that led to the discovery of the vitamins. The sharp definition and the severity of the symptoms of these diseases testify to the fact that each of the vitamins plays a decisive role in one or more of the vital processes in the cells and tissues of the body. So specific and immediate is the efficacy of a given vitamin in its action upon the deficiency disease with which it is identified that one might take it to be a “wonder drug.” One needs to be reminded that vitamins are foods. They catalyzed the evolution of our species. They remain essential to our existence and our health. A striking characteristic of human beings and other living organisms is that they carry out thousands of different chemical reactions between sub stances that under ordinary conditions would not react with one another. Every day we burn about a pound of fuel, carbohydrate (mainly glucose) and fat, to provide body heat and energy. This combination takes place at body temperature, 98.6°F. But we know that these substances—starch, sugar, butter, etc.—do not burn at ordinary temperatures. It may even be hard to make them burn at a much higher temperature. For example, if you take a cube of sugar (sucrose) and hold the flame of a burning match to one corner, you will find that some of the sugar will melt, but it will not catch fire. -
How is it possible for living organisms to make carbohydrates and fats react with oxygen (burn) at body temperature? The answer is that they make use of auxiliary substances that have the power to speed up chemical reactions without any change in themselves. These substances are called catalysts; they are said to catalyze the reactions. If you put a very small amount of cigarette ash (if you know someone who still smokes) on the corner of a cube of sugar and touch a match flame to it, the sugar will catch fire and will continue to burn until the cube is consumed. The burning takes place on the surface of the ash particles, which themselves remain unchanged, so that a little bit of ash can catalyze the combustion of a large amount of sugar. The catalysts in the human body are called enzymes (named after the Greek word for yeast); yeast contains enzymes that accelerate the process of fermentation, the conversion of glucose into alcohol by reaction with oxy gen. They are proteins, with large molecules, often containing ten thousand or twenty thousand atoms. They are highly specific in their enzymatic activity, often able to speed up only a single biochemical reaction or a few similar ones. There may be as many as fifty thousand different kinds of enzymes in the body of a single human being. Some enzymes are pure protein, just a folded chain of amino-acid resi dues. Others consist of a protein molecule with something added, an addi tion required to give it the ability to catalyze its specific chemical reaction. This added part is called a coenzyme. Both metals and vitamins (or substances made from vitamins, such as thiamine diphosphate, made by combining thiamine, vitamin B,, and phos phoric acid) serve as coenzymes in many enzyme systems in the human body. For example, the molecule of alcohol dehydrogenase, which catalyzes the oxidation of alcohol to acetate in the liver, contains two atoms of zinc, which are required for its enzymatic activity. One enzyme, cysteamine oxi dase, contains an atom of iron, an atom of copper, and an atom of zinc. The reason that a trace element such as molybdenum is required in extremely small amounts is that it serves as a coenzyme, permitting the active enzyme to work over and over again in catalyzing a chemical reaction that is essen tial for health. In the same way only a small daily intake of a vitamin may be required (a few millionths of a gram of B12), but through its catalytic activity it produces a far larger amount of some vital substance. Most of the vitamins are known to serve as coenzymes in a number of enzyme systems. Pantothenic acid, for example, is a part of coenzyme A, which combines with the protein apoenzymes (passive enzymes) to give active enzymes required for many reactions. One of these reactions is the conversion in the brain of choline to acetylcholine, one of the messengers involved in brain activity. Nicotinamide, one form of vitamin B3, is an
essential part of two important coenzymes, diphosphopyridine nucleotide and triphosphopyridine nucleotide. There is some evidence that these co enzymes are involved in two hundred enzyme systems, and in fact the number may be much greater. Vitamin B6, usually as pyridoxal phosphate, is required as a coenzyme for more than one hundred known enzyme sys tems, and the other vitamins, with vitamin C an exception, also serve as coenzymes. Often the apoenzyme available in the body is only partially converted to active enzyme. The amount of active enzyme can be increased by increasing the intake of the vitamin that serves as coenzyme. This effect is an impor tant part of the rationale behind the modern science of nutrition, with its emphasis on optimum intakes. The devastating symptoms of scurvy, expressed in the wasting and disin tegration of the tissues of the body, suggested a large and ubiquitous pres ence in the body for the factor in nutrition we know today as vitamin G. Fortunately the disease yielded to the simple therapy of supplying a small ration of the foods that contain the vitamin. The therapy worked its cure long before the vitamin was identified and still longer before its biochemical role began to be as well understood as it is today. While much remains to be learned, more is known about the function of vitamin G than of any other vitamin. For that reason, as well as for its well-established supreme importance, we shall here consider at closer range what vitamin G—also called ascorbic acid—is, what it does in the body, and how it works. Ascorbic acid is a white, crystalline powder, which dissolves readily in water. Its solution has an acidic taste, resembling that of orange juice. It is a weak acid, somewhat stronger than acetic acid found in vinegar, but weaker than citric acid (in lemons and grapefruit), lactic acid (in sour milk and sauerkraut), and tartaric acid (in grapes). In body fluids, which are usually neither acidic nor basic, ascorbic acid is completely dissociated into an ascorbate ion and a hydrogen ion. The hydrogen ion combines with basic groups of proteins or with a bicarbonate (H C 03) ion. It is the ascor bate ion that participates in the many physiological reactions that require vitamin C, especially the scurvy-preventing synthesis of the critically im portant protein collagen. Vitamin G may also be taken as the salts of ascorbic acid, in particular sodium ascorbate and calcium ascorbate. These molecules dissolve in the body fluids to produce ascorbate ions, which have the same properties and physiological action as the ascorbate ion from ascorbic acid. Vitamin G may thus be taken by mouth, in solution or in tablet form, as ascorbic acid, as sodium ascorbate, or as calcium ascorbate. Only the latter two, the salts, can be taken by intravenous injection, however, because the acid solution damages the veins or tissues.
The ways in which ascorbic acid functions in the human body relate first to the fact that it engages on both sides of the universal oxidation-reduction reaction that subtracts or adds hydrogen atoms to a molecule. It is readily oxidized to dehydroascorbic acid by the surrender, to oxidizing agents, of the two hydrogen atoms (designated by the symbol H) shown attached to the two oxygen atoms (O) at the top of the structural diagrams of the two molecules displayed below:
(For the structure of ascorbic acid in three-dimensional space, see the illus tration on page 68.) This action is readily reversible, for dehydroascorbic acid acts as a strong oxidizing agent, and by picking up two hydrogen atoms is reduced to ascor bic acid. It is likely that the reducing power of ascorbic acid and the oxidiz ing power of dehydroascorbic acid are responsible for some of the physio logical properties of the substance. The synthesis of collagen, for which vitamin C is essential, proceeds in the body as one of its major manufacturing enterprises. A person who is dying of scurvy stops making this substance, and his body falls apart—his joints fail, because he can no longer keep the cartilage and tendons strong, his blood vessels break open, his gums ulcerate and his teeth fall out, his immune system deteriorates, and he dies (Cameron, 1976). Collagen is a protein, one of the thousands of different kinds of proteins in the human body. Most proteins occur in only small amounts; the various enzymes, for example, are so powerful in their ability to cause specific chemical reactions to take place rapidly that only a gram or two or even a few milligrams may be needed in the body. There are a few exceptions. In the red cells of the blood there is a great amount of hemoglobin, amounting to 1 percent of a person’s weight. Hemoglobin, however, does not get the prize. There is even more collagen in the skin, bones, teeth, blood vessels, eye, heart, and, in fact, essentially all parts of the body. Collagen as strong white fibers, stronger than steel wire of the same weight, and as yellow
elastic networks (called elastin), usually together with macropolysaccha rides, constitutes the connective tissue that holds our bodies together. When bones, skin, cartilage, and other parts of the animal body are boiled in water for a long time, the molecules are hydrolyzed (react with water molecules) to form smaller molecules, called gelatin. Gelatin is a reasonably good food, but it lacks the essential amino acids phenylalanine and tryptophan. Soup stock is a gelatin solution, and aspic and, of course, gelatin desserts are based on gelatin. Like other proteins, collagen consists of polypeptide chains; the long chains of this fibrous molecule contain about one thousand amino-acid resi dues, about sixteen thousand atoms. It differs from almost all other proteins in being substantially composed of but two amino acids, glycine and hydroxyproline. Collagen is a kind of supermolecule, however, in its three dimensional architecture. The polypeptide chains of the two amino acids, alternating with one another and punctuated by the presence of certain other amino acids, are coiled in a left-handed helix. Three of these helical strands are twisted around one another, like the strands of a rope, in a right-handed superhelix, to compose the complete molecule (see the draw ing on page 70 and 71 and the photograph on page 72). Understandably, the synthesis of this structure proceeds in steps. While it has been known for half a century that vitamin C is essential to the manufacture of collagen, the process is only now yielding to inquiry. It ap pears that vitamin C is involved at every step. First a three-stranded structure is assembled, with the amino acids gly cine and proline as its principal components. This is not yet collagen but its precursor, procollagen. A recent study shows that vitamin C must have an important role in its synthesis. Prolonged exposure of cultures of human connective-tissue cells to ascorbate induced an eightfold increase in the Molecular structure of vitamin C Ascorbic acid has a distinctive shape or configuration in three-dimensional space, shown here in the conventional ball (atoms) and stick (atomic bonds) model, that underlies its function in the biochemistry of the body. Four carbon atoms (indicated by the letter C) and an oxygen atom (O) form a central pentagonal ring, shown tilted at an angle to the plane of the page. The four bonds on each carbon atom—which give organic molecules their endless structural diversity—bind each of them to four other atoms or to three others with a double bond binding one of the three. The bottom carbon in the ring holds a large side group, which extends upward above the plane of the page. Attached to the two carbons in this side group are two hydroxyl groups, an oxygen atom with an attached hydrogen. Vitamin C is needed for the vital hydroxylation reactions that introduce hydroxyl groups into many other molecules, notably the adrenal hormone and the collagen molecule that forms connective tissue (see the illustration on page 70). The shape of the vitamin-C molecule fits it, hand and glove style, to the shape of the enzymes with which it works in these reactions.
Structure of collagen The collagen molecule is stronger than steel wire of the same weight. One of the most abundant proteins, it supplies the body’s connective tissue, the natural plastic of which the body is largely made. Vitamin C plays essential roles in its synthesis, apparently at every stage (see page 68). Collagen owes its properties not only to its chemical composition but also to the physical arrangement of its component atoms in three-dimensional space. The atoms—of carbon, hydrogen, oxygen, and nitrogen—are organized in three polypeptide chains. Each of these chains is coiled in a left-handed helix, and the three chains are twisted around one another, as the strands of a rope, to form a right-handed superhelix, one full turn of which is shown schematically at left on the opposite page. The illustration on this page shows the arrangement of the atoms in one full turn of the left-handed helix of the polypeptide chain (in the small box on the opposite page) in the conventional ball (atoms) and stick (atomic bonds) model. A polypeptide chain is assembled by the head-to-toe linkage of amino acids by peptide bonds. These bonds tie the nitrogen atom (N) in one amino acid to a carbon atom (C) in another. In the three peptide groups in the full turn of the helix shown here, note the double bond that ties the carbon to the nitrogen in the middle peptide group. This is the peptide bond; it could as well be shown binding the carbon to the oxygen (O), as it is in the peptide groups at the top and bottom of the turn. The resonating of the bond between these two alignments holds the six atoms of the peptide group flat in a plane. (The six atoms, from the top, are a carbon festooned with two hydrogen [H] or with one hydrogen and a side group [R], which are outside the plane, the carbon, the oxygen bonded to the carbon, the nitrogen, the hydrogen bonded to the nitrogen, and a second festooned carbon.) By contrast, the single bond that links the nitrogen to the festooned carbon that is shared with the neighboring peptide group permits the planar peptide groups to rotate about a common axis and form the helix. Some 1000 peptide groups composed of 16,000 atoms make up the thin fiber of the collagen molecule, 2800 angstroms (1 A is one hundred-millionth of a centimeter) long and only 72 A thick. The long collagen molecules link up to form still longer strands. These strands, with the collagen molecules overlapping by a quarter of their length (700 A), line up and cross-link to form the collagen fibril at far right. The periodic striations in the collagen fibril (see electromicrograph on page 72) reflect the linkage and cross-linkage of the overlapping molecules of collagen in the fibril.
Collagen fibrils Dark bands spaced approximately 700 angstroms (A) apart appear where the intricate fine structures of collagen molecules (overall length approximately 2800 A) overlap (see the illustration on page 71). (Courtesy of Dr. Jerome Gross, Massachusetts General Hospital )
synthesis of collagen with no increase in the rate of synthesis of other proteins (Murad et al., 1981). Since the production of procollagen must precede the production of collagen, vitamin C must have a role in this step—the formation of the polypeptide chains of procollagen—along with its better understood role in the conversion of procollagen to collagen. That conversion involves a reaction that substitutes a hydroxyl group, OH, for a hydrogen atom, H, in the proline residues at certain points in the polypeptide chains, converting those residues to hydroxyproline. This hydroxylation reaction secures the chains in the triple helix of collagen. The hydroxylation, next, of the residues of the amino acid lysine, transforming them to hydroxylysine, is then needed to permit the cross-linking of the triple helices into the fibers and networks of the tissues. These hydroxylation reactions are catalyzed by two different enzymes: prolyl-4-hydroxylase and lysyl-hydroxylase. Vitamin C also serves with them in inducing these reactions. It has recently been shown by Myllyla and his colleagues that, in this service, one molecule of vitamin C is de stroyed for each H replaced by an OH (Myllyla et al., 1984). We have come upon two big reasons why we require for good health much larger amounts of vitamin C than are present in the plants we use as food. First, there is the body’s continuing need for the synthesis of large amounts of collagen for growth and for replacement of the collagen degraded by daily wear and tear. Second, vitamin C, in the critical reac tions that assemble collagen in the tissues, does not serve merely as a cata lyst but is destroyed. The function of vitamin C involves another aspect of the molecule: its architecture in the three dimensions of space. Vitamin C is a chiral sub stance: its molecules have handedness. (The word chiral is derived from the Greek word cheir3 which means “hand.”) Ascorbic acid is often called Lascorbic acid, to identify the molecules as left-handed (L for levo} “left”) rather than right-handed (D for dextro3 “right”). Like a single hand, the molecule of L-ascorbic acid is not identical with its mirror image (see illus tration on page 68).
Chirality may almost be said to be characteristic of life. It is true that some inorganic substances are chiral: the mineral quartz, for example, forms right-handed and left-handed crystals, as do some other minerals, but living organisms have exploited chirality to a far greater extent than has the inorganic part of nature. The organic molecules that life processes build around the carbon atom derive their chirality from a property of carbon atoms. On its four bonds carbon may gather four different kinds of atoms or groups; such molecules must be either right-handed or left-handed and, like hands, differ from their mirror image. Our principal macronutrients are carbohydrates, fats, and proteins. All of the carbohydrates are chiral. This fact is illustrated in some of their
names. Glucose is also called dextrose; its molecules may be considered to be right-handed. Our principal food starch, which is a sort of polymer (a condensation product of glucose, with elimination of water), may also be said to be right-handed. Starch is digested to form glucose by enzymes that are themselves chiral—these enzymes can digest ordinary right-handed starch (D-starch), but not left-handed starch. Fructose (fruit sugar) is also called levulose; it may be said to be a left-handed sugar. Its left-handed ness accounts for the fact that it is not all burned for its energy content, as glucose is, but serves in part as a raw material for the synthesis of cholesterol. Most of the fats are not chiral, but some related substances (lipids) are. An example is vitamin E: D-alpha-tocopherol and L-alpha-tocopherol have different vitamin-E activity. Proteins are chiral. These extremely important macromolecules (a hu man being may synthesize fifty thousand different kinds of protein mole cules to do different jobs in the body) consist of long chains of amino-acid residues, all of which are chiral, except those of the simplest amino acid, glycine. It is a remarkable fact that all of the more than twenty amino acids that make up the proteins in human beings, in other animals, and in plants have the same handedness: they are all L-amino acids, except for glycine, which is identical with its mirror image. We can understand now why living organisms are made of only one kind of amino acids. The principal ways in which the chains of amino-acid residues are folded in stable proteins are known, and we can see that these structures are stable when they are made of one kind, either the D kind or the L kind, but they cannot be made with D and L mixed. The earth might just as well be populated with living organisms made with D-amino acids as with those made with L-amino acids. A man who was suddenly converted into an exact mirror image of himself would not at first know that anything had changed; he could drink water, inhale air and use the oxygen molecules in it for combustion, exhale carbon dioxide, and carry on other bodily functions just as well as ever—so long as he did not eat any ordinary food. If he were to eat ordinary plant or animal food, he would find that he could not digest it. (In Lewis Carroll’s Through the Looking Glass Alice said, “Perhaps looking-glass milk isn’t good to drink.” We know now that she was right in her surmise.) This mirror-image man could be kept alive only on a diet containing synthetic D-amino acids, made in the chemical laboratory. He could not have any children, unless he could find a wife who had been subjected to the same process of reflection into a mirror image of her original self. Also he would die of scurvy, even if he had plenty of ordinary vitamin C, be cause vitamin C is itself a chiral molecule, L-ascorbic acid.
The chirality of L-ascorbic acid may be plainly seen in the diagram of its structure in three-dimensional space shown on page 68. The carbon atom (G) at the bottom of the pentagonal ring has attached to it a carbon atom on one side of it in the ring and an oxygen (O) on the other, a hydrogen (H) atom, and a side group of nine atoms. These four different attached entities make this carbon atom chiral. That is, the mirror image of this atom and its attachments differs from it as the mirror image of a hand differs from the hand. The first atom of the side chain, a carbon, is also chiral. It also has four different entities attached to it: the pentagonal ring, a hydroxyl group (an oxygen atom and attached hydrogen atom), a hydrogen atom, and a carbon (with two hydrogens and a hydroxyl group attached to it).
Ascorbic acid has accordingly four stereoisomers—four molecules with identical atomic constituents linked to one another in the same order but arrayed differently in three-dimensional space. We may therefore call the molecule shown in the illustration LL and the others LD, DL, and DD. LL is the ordinary vitamin C, L-ascorbic acid. DD is its exact mirror image, with properties exactly the same as those of L-ascorbic acid (unless they involve chirality)—the same melting point and the same solubility in water—but one rotates the plane of polarized light in a clockwise way and the other in the opposite way (but through exactly the same angle). But the DD sub stance, which is called D-xyloascorbic acid, has no vitamin-C activity. The substances LD and DL, which are mirror images of each other, also provide no protection against scurvy.
This fact shows that the action of vitamin C does not depend simply on its activity as a reducing or oxidizing agent, which it has in common with its stereoisomers. Instead it depends upon the shape of its molecules, which presumably fit into a complementary cavity in the hydroxylation enzymes with which it works in the synthesis of collagen and thereby forms a reac tive complex. Further study is needed to determine the structure of these enzymes and of others that can form such complexes with vitamin C. There are probably many different kinds, because vitamin C carries on so many different functions in our bodies. The hydroxylation reaction, which vitamin C promotes in the synthesis of collagen, has a role in many other physiological processes. A substance called carnitine, for example, helps to supply the fuel that energizes the contraction of muscle fiber. Its synthesis from the amino acid lysine takes place through five successive reactions, each catalyzed by a specific enzyme. The second and fifth involve hydroxylation, for which vitamin C is needed. In the adrenal glands, hydroxylation reactions mediated by vitamin C, present in large amounts, similarly convert the amino acid tyrosine first to dopa, then to dopamine and at last to noradrenaline in the manufacture of
the all-important hormone adrenaline, which floods the body in moments of stress and activates the muscles for flight or fight. In this critical cycle the ascorbic acid is reconstituted from semidehydroascorbate by a special elec tron-transport mechanism, and so the vitamin is not destroyed. This review of the function of vitamin G in the biochemistry of the body explains why we require large intakes of this vitamin, larger than those of other vitamins and larger than is supplied by the usual quantities of vegeta bles and fruits consumed in the diet. Setting aside the factor of biochemical individuality, to be discussed in the next chapter, for a moment, we may ask what is the optimum daily supplementary intake of vitamin G. Plants need only small amounts of this vitamin. They do not manufac ture collagen to make their structures strong; they use a carbohydrate, cellulose, for this purpose. I have checked the amounts of various vitamins present in 110 raw, natural plant foods, as given in the tables in the metab olism handbook published by the Federation of American Societies for Experimental Biology (Altman and Dittmer, 1968). When the amounts of vitamins corresponding to one day’s food for an adult (the amount that provides 2500 kilocalories [kcal] of energy) are calculated, it is found that for most vitamins this amount is about three times the RDA of the Food and Nutrition Board. For ascorbic acid, however, the average amount in the daily ration of the 110 plant foodstuffs is 2300 milligrams (mg), about forty times the amount recommended as the daily allowance for a person with a requirement of 2500 kcal per day (see the table in Chapter 8). This calculation suggests that the Recommended Daily Allowance (RDA) ought to prescribe at least forty times its stingy 60 mg of Vitamin C. The average ascorbic-acid content of the fourteen plant foodstuffs richest in this vitamin is 9.4 grams (g) per 2500 kcal. Peppers (hot or sweet, green or red) and black currants are richest of all the foods in the table, with 15 g per 2500 kcal. The foregoing argument represents an extension and refinement of argu ments advanced by the biochemists G. H. Bourne and Irwin Stone. In 1949 Bourne pointed out that the food ingested by the gorilla consists largely of fresh vegetation, in quantity such as to give the gorilla about 4500 mg of ascorbic acid per day, and that before the development of agriculture humans existed largely on green plants, supplemented with some meat. He concluded that “it may be possible, therefore, that when we are arguing whether 10 to 20 mg of vitamin G a day is an adequate intake we may be very wide of the mark. Perhaps we should be arguing whether 1000 or 2000 mg a day is the correct amount.” Stone (1966a) quoted this argument and supplemented it by consideration of the rate of manufacture of ascorbic acid by the rat. The rat under normal conditions is reported to synthesize ascorbic acid at a rate between 26 mg per day per kilogram of body weight
(Burns, Mosbach, and Schulenberg, 1954) and 58 mg per day per kilogram of body weight (Salomon and Stubbs, 1961). If the assumption is made that the same rate of production would be proper for a human being, a person weighing 70 kilograms (kg, 154 pounds) should ingest between 1800 and 4100 mg per day under ordinary circumstances. Other animals, including the goat, cow, sheep, mouse, squirrel, gerbil, rabbit, cat, and dog, also manufacture ascorbic acid at a high rate, averag ing about 10,000 mg per day for 70 kilograms (kg) (154 pounds) of their body weights (Chatterjee et al., 1975). It is hard to believe that these ani mals would make this large amount of ascorbic acid if it were not beneficial to them, and it is also hard to believe that humans are so much different from other animals that they can keep in the best of health with only twohundredths of the amounts that animals use. If the need for ascorbic acid in our diet were really as small as the RDA published by the Food and Nutrition Board, then the mutation that deprived the primates of the ca pacity to synthesize their own vitamin C would surely have occurred six hundred million years ago, and dogs, cows, pigs, horses, and other animals would be obtaining ascorbic acid from their food, instead of manufacturing it in their liver cells. I conclude, therefore, that 2300 mg per day is less than the optimum rate of intake of ascorbic acid for an adult human being. In general, the dietary requirements of humans have been found to be closely similar to those of other primates, and studies of vitamin C in these primates should yield valuable information about the optimum human in take of this vitamin. Monkeys are used in large numbers of medical re search. As I mentioned in Chapter 1, much effort has been devoted by the Subcommittee on Laboratory Animal Nutrition to finding the intakes of various nutrients that puts them in the best of health. These careful studies have led to the formulation of several, rather similar recommended diets for laboratory monkeys. The amount of ascorbic acid in these diets lies in the range of 1.75 g per day to 3.50 g per day, scaled up to 70 kg of body weight; the 1.75 g per day scaled from the prescription for rhesus monkeys (Rine hart and Greenberg, 1956) and 3.50 g per day from that for squirrel mon keys (Portman et al., 1967). These monkeys weigh only a few kilograms, but there is little doubt that the need for ascorbic acid is proportional to body weight, for the amounts manufactured by animals that have the abil ity to make this substance are found to be rather closely proportional to body weight over a tremendous range, from a 20-g mouse to a 70-kg goat. From these studies with monkeys we may conclude that the requirement of vitamin C by humans might lie in the range of L75 g to 3.5 g per day. Additional evidence has been provided by a study of the optimum intake of ascorbic acid by guinea pigs. Yew (1973) found that observations of growth rates both before and after surgical stress; recovery times after anes-
thesia; and the times needed for scab formation, wound healing, and the production of hydroxyproline and hydroxylysine during wound healing all support the conclusion that young guinea pigs ordinarily need about 5.0 mg per 100 g of body weight per day and that under stress the needs are even higher. For humans the corresponding intake is 3.5 g per day under ordi nary conditions, a larger amount under stress. Why have not similar studies been carried out with human beings? Part of the answer is that it is much harder to study humans than animals. Another part is that many physicians and nutritionists seem to have ac cepted the idea that vitamin C has no value for human beings except to prevent scurvy and that it would be a waste of effort to attempt to deter mine the optimum intake. Still another aspect of this matter is that these authorities persist in ignoring the many studies that have been carried out demonstrating that an intake of several grams per day leads to improved health. I conclude that the optimum daily intake of ascorbic acid for most adult human beings lies in the range 2.3 g to 10 g. The amount of individual biochemical variability (Chapter 10) is such that for a large population the range may be as great as from 250 mg to 20 g or more per day. These amounts are much larger than the RDA of vitamin C published of the Food and Nutrition Board, as previously noted. The recommendation of this board, said to be designed for the maintenance of good nutrition of practically all healthy people in the United States, is 35 mg per day for infants, 45 mg per day for children, increasing to 60 mg per day for adults (80 for pregnant women and 100 for lactating women). In making its recommendation the board stated that the minimum daily intake of ascorbic acid needed to prevent scurvy is about 10 mg, and that the somewhat larger amounts recommended should provide a generous increment for individual variability and a surplus to compensate for potential losses in food. The idea that beneficial effects would result from a larger intake of ascorbic acid was rejected, on the basis of reports that physical and psychomotor per formances of men had not been improved by supplements of between 70 mg and 300 mg of ascorbic acid per day, and that the occurrence of bleeding gums in military personnel was not affected by supplements of 100 mg or 200 mg per day for periods of three weeks. There are, however, many published reports about beneficial effects of vitamin C ingested in larger amounts. Ascorbic acid is not a dangerous substance. It is described in the medical literature as “virtually nontoxic.” Guinea pigs that were given, orally or by intravenous infusion (of sodium ascorbate, the sodium salt of ascorbic acid), 0.5 percent of their body weight per day for a period of days showed no symptoms of toxicity (Demole, 1934). This amount corresponds for a hu man being to about 350 g (three quarters of a pound) per day. Many dogs
and cats have been given large doses for control of distemper, influenza, rhinotracheitis, cystitis, and other diseases, with beneficial results and no signs of toxicity (Belfield and Stone, 1975; Belfield, 1978, 1982). The amount used was 1 g per pound of body weight per day, injected intrave nously (in two doses, morning and afternoon), corresponding to about 150 g per day for an adult human being. Human beings themselves have taken 10 to 20 g of vitamin C every day for twenty-five years with no development of kidney stones or other side effects (Klenner, 1971; Stone, 1967). Patients with glaucoma have been treated with about 35 g of vitamin C (0.5 g per kg body weight) each day for more than seven months (Virno et al., 1967; Bietti, 1967). The only side effect reported was looseness of the bowels during the first three to four days. Patients with viral diseases or schizo phrenia have received as much as 100 g per day with no symptoms of toxicity (Klenner, 1971; Herjanic and Moss-Herjanic, 1967). One cancer patient has taken 130g per day for nine years, with benefit. A large amount (several grams) of ascorbic acid taken without other food may cause an upset stomach and looseness of the bowels in some people, but more serious side effects have not been reported. Ascorbic acid may be described as no more toxic than ordinary sugar (sucrose), and far less toxic than ordinary salt (sodium chloride). There is no reported case of the death of any person from eating too much ascorbic acid, nor, indeed, of serious illness from this cause. It might be possible to ingest from the food we eat the amount of vitamin C that I recommend as optimum. This would require, however, a cuisine loaded with peppers (hot or sweet, green or red) and black currants. Other plant foods afford less than the 350 mg of vitamin C per 100 g measured in these foods. Orange juice, lemon juice, lime juice, grapefruit juice, tomato juice, mustard greens, spinach, and brussel sprouts contain a good quantity of ascorbic acid, from 25 mg to 100 mg per 100 g. Green peas and green beans, sweet corn, asparagus, pineapple, tomatoes, gooseberries, cranber ries, cucumbers, and lettuce contain from 10 mg to 25 mg per 100 g. Some what smaller amounts—less than 10 mg per 100 g—are found in eggs, milk, carrots, beets, and cooked meat. (See the table on page 61.) The ascorbic acid in foodstuffs is easily destroyed by cooking at high temperatures, especially in the presence of copper and to some extent of other metals. Cooked foods usually retain only about half of the ascorbic acid present in the raw foods. The loss of the vitamin can be kept to a minimum by cooking for a short period of time, with a minimum amount of water and with the water not discarded, because it has extracted some of the vitamin from the food. A good ordinary diet, including green vegetables and orange or tomato juice, may provide 100 mg of ascorbic acid per day. Many people, however, do not obtain even this rather small amount. A 1971-1972 study by the
Health Resources Administration of the U.S. Department of Health, Edu cation, and Welfare of 10,126 people aged one to seventy-four in ten repre sentative geographical areas of the country found that half of the people received less than 57.9 mg of vitamin C per day and about one-third of the people received less than the RDA of 60 mg per day for an adult (Abraham et al., 1976). Only 30 percent had a daily intake greater than 100 mg, and only 17 percent greater than 150 mg. The average intake of people below the poverty level is 78 percent of that of the whole population, and 57 percent of them receive less than the RDA. Fortunately, this important dietary requirement may be met in any amount desired—from the optimum daily intake to the larger therapeutic amounts which we shall consider later in this book—by ingesting supple mental quantities of the pure substance, crystalline ascorbic acid, or one of its salts.
10.B i o c h e m
ic a l
I n d iv id u a lity
The genetic mutation that deleted the capacity to manufacture vitamin C in the primate line presents one vivid example of the countless genetic vari ations from which natural selection produced the diversity of biological organisms we know in the world today. Such biochemical insight permits us to see evolution, as it were, from the inside. It gives a quantitative mea sure of the wealth of differences among individuals within a single species upon which natural selection acts in choosing the “fittest.” It shows each of us human beings to possess a biochemical individuality that is scarcely expressed in (but only partly accounts for) the differences we observe in one another. Let us consider some genetic characteristic, such as the weight of the liver relative to the total weight of the human being or the concentration of a certain enzyme in the red cells of the blood. It is found that, when a sample of a hundred human beings is studied, this characteristic varies over a wide range. The variation often is approximately that given by the standard, bell-shaped probability function. It is customary to say that the “normal” range of values of the characteristic is that range within which 95 percent of the values lie and that the remaining 5 percent of the values, represent ing the extremes, are abnormal. If we assume that five hundred characteris tics are independently inherited, then we can calculate that there is only a
small chance, 3 percent, that one person in the whole population of the world would be normal with respect to each of these five hundred char acteristics. It is estimated, however, that a human being has a complement of one hundred thousand genes, each of which serves some function, such as con trolling the synthesis of an enzyme. The number of characteristics that can be variable, because of a difference in the nature of a particular gene, is presumably somewhere near one hundred thousand rather than only five hundred; and accordingly we reach the conclusion that no single human being on earth is normal (within the range that includes 95 percent of all human beings) with respect to all characteristics. This calculation is, of course, oversimplified. It helps emphasize, however, that human beings differ from one another and that each human being must be treated as an individual, biologically as well as morally. The species Homo sapiens is more heterogeneous, with respect to genetic character, than most other animal species. Nevertheless, heterogeneity has been found also for laboratory animals such as guinea pigs. It was recog nized long ago that guinea pigs fed the same scurvy-producing diet, con taining less than 5 milligrams (mg) of ascorbic acid per day per kilogram of body weight, differed in the severity of the scurvy that they developed and in the rapidity with which they developed it. A striking experiment was carried out in 1967 by Williams and Deason. These investigators obtained some male weanling guinea pigs from an animal dealer. After a week of observation during which the guinea pigs were on a good diet, including fresh vegetables, they were placed on a diet free of ascorbic acid or with known amounts added. They were divided into eight groups, each of ten to fifteen guinea pigs, with one of the groups receiving no ascorbic acid and the other groups receiving varying amounts through a pipette into the mouth. About 80 percent of the animals receiving no ascorbic acid or only 0.5 mg per kilogram per day developed signs of scurvy, whereas only about 25 percent of those receiving between 1 mg and 4 mg per kilogram per day, and none of those receiving 8 mg per day or more, developed these signs. These results agree with the customary statement that about 5 mg per kilo gram per day of ascorbic acid is required to prevent scurvy in guinea pigs. It was observed, however, on the one hand, that two animals receiving only 1 mg per kilogram per day remained healthy and gained weight over the entire period of the experiment (eight weeks). One of them showed a total gain in weight larger than that for any animal receiving two, four, eight, or sixteen times as much ascorbic acid. On the other hand, seven of the guinea pigs receiving 8, 16, or 32 mg per kilogram per day were unhealthy and showed very small growth during the first ten days on the diet. They were then provided with a larger amount of the vitamin, five of them with 64 mg per kilogram per day and two of them
with 128 mg per kilogram per day. These animals showed a remarkable response: whereas they had grown only 12 grams (g), on the average, in a period of ten days on the smaller amounts of ascorbic acid, their growth during the ten-day period after beginning to receive the larger amounts was, on the average, 72 g. The indicated conclusion is that these animals, seven of the thirty that were given between 8 mg and 32 mg per kilogram per day, required more vitamin C for good health than the others. Williams and Deason (1967) reached the conclusion that there is at least a twentyfold range in the vitamin-C needs of individual guinea pigs in a population of a hundred. They pointed out that the population of human beings is presum ably not more uniform than that of the guinea pigs used in their experi ments and that accordingly the individual variation in the vitamin-C needs of humans is probably just as great. I have accepted their conclusion, and similar conclusions reached by other investigators, in suggesting that the optimum rate of intake of ascor bic acid by human beings may extend over a wide range, perhaps the eightyfold range from 250 mg per day to 20 g per day or an even wider range. Vitamin C has been under investigation, reported in thousands of scien tific papers, ever since it was discovered fifty years ago. The reader of this book might well be justified in asking first, why the range of values of the optimum intake of this important substance was not reliably determined long ago and, second, why no one can tell him or her what amount to take to be in the best of health. Part of the answer to the first question is that only a very small amount of the vitamin, perhaps 10 mg per day, is enough to keep most people from developing scurvy, and physicians and nutrition ists accepted the idea that no larger amount is needed. Even though some physicians had observed forty or fifty years ago that amounts a hundred or a thousand times larger have value in controlling various diseases, as de scribed elsewhere in this book, the medical profession and most scientists ignored the evidence. Another part of the answer to this first question is that studies that would yield the answer can be carried out only with great effort and at great expense. It is much easier to investigate some powerful drug that has an immediate beneficial effect on the patient (although it is harder to check the possible long-term damage that the powerful drug may do to some fraction of the people for whom it is prescribed). Several excellently planned and executed epidemiological studies involving nutritional and other factors in relation to the incidence of disease and the chance of death at various ages have been carried out. In some of these studies the nature of the ingested food has been tabulated, and the amounts of vitamin C and other vitamins in the diet have been calculated using tables giving the vitamin contents of various foods. Some of these studies show that the
incidence of disease and the chance of death at each age are less for people with a larger intake of vitamin C (and also for some other vitamins) than for those with a smaller intake. In these studies, however, the intakes of vitamin C are small; usually, for example, 0 mg to 50 mg per day for the low-intake group and between 50 mg and 100 mg for the high-intake group. In their San Mateo County, California, study, Lester Breslow and his colleagues in 1948 interviewed 577 randomly selected residents of the county who were fifty years old or older. They obtained much information about their state of health and about environmental, behavioral, and nutri tional factors that might affect it. After seven years they examined the death records and compared the age-corrected death rates for the subpopulations related to the different factors. Of all of these factors, the intake of vitamin C was found to have the greatest correlation with the age-corrected death rate, even greater than that for cigarette smoking (Chope and Breslow, 1955). Whereas cigarette smokers have at each age twice the chance of dying that a nonsmoker has, the persons with a lower intake of vitamin C (calcu lated from the content of vitamin C in the food that they ate) had a chance of dying 2.5 times greater than the persons with a higher intake of the vitamin. The amount of illness was also correspondingly greater. This dif ference means that the length of the period of good health and of life was ten years greater for the persons with the higher intake than for those with the lower intake of vitamin C. The dividing line was 50 mg per day, approximately equal to the recommended dietary allowance. The average intake of the low-intake group was 24 mg per day and that of the highintake group was 127 mg per day.* It is interesting that drinking a large glass of orange juice each day (about 90 mg of ascorbic acid in 6 ounces of juice) or taking a 100-mg tablet each day would put a person in the highintake group. Part of the improvement in health in the high-intake group may be attributed to other substances in the foods that provided the extra vitamin C. There is no doubt that orange juice, lettuce and other vegetables, and fruits contain important nutrients in addition to vitamin C. But the effect of a higher intake of vitamin A in improving the health was found in the San Mateo study to be only half as great as that of vitamin C, and the effect of *These averages are calculated on the assumption that the distribution of intakes for each of the two groups is the same as that for the corresponding groups (age over sixty) in the First Health and Nutrition Examination Survey, 1971-72 (Abraham, Lowenstein, and Johnson, 1976).
niacin, one of the B vitamins, was only one-quarter as great. The foods with a high content of vitamin A and niacin, although they have value in improving the health, are not so valuable as those with a high content of vitamin C. When vitamin C is taken by mouth, most of it is absorbed into the blood through mucous membranes of the mouth and the upper part of the small intestine. If the amount taken is rather small, up to 250 mg, about 80 percent is absorbed into the blood. With larger doses the amount absorbed is less, about 50 percent for a dose of 2 g and still smaller for larger doses (Kulber and Gehler, 1970). Accordingly it is more economical to ingest vitamin C in smaller doses, such as 1 g every three hours, than to take a single, much larger dose once a day. Also, a quantity of sodium ascorbate injected into the bloodstream is more effective in the treatment of disease than the same amount taken by mouth. For a small daily intake of ascorbic acid, up to about 150 mg, the concen tration in the blood plasma is nearly proportional to the intake: this concen tration is about 5 mg per liter for a daily intake of 50 mg, 10 mg per liter for 100 mg, and 15 mg per liter for 150 mg. Above an intake of 150 mg per day the concentration in the blood increases much less with increasing intake, reaching about 30 mg per liter for an intake of 10 g per day (ascor bic acid plus dehydroascorbic acid; Harris, Robinson, and Pauling, 1973). The reason for this change when the intake exceeds about 150 mg per day is that a larger amount of the vitamin then begins to be excreted in the urine. One of the functions of the kidney is to clear the blood of unwanted and harmful molecules, the molecules of toxic substances that have got into the blood through the food or impure air or of waste products such as urea, the compound of nitrogen that is formed when old protein molecules in the body are degraded. Every twenty minutes the entire volume of the blood passes by a set of molecular filters in the two million glomeruli of the kidney. In the glomeruli the capillaries through which the blood is flowing have small holes in them. These holes, the pores of the glomerular filter, are small enough that the protein molecules in the blood, such as the anti bodies (globulins) that protect us against disease, cannot pass through them, but water molecules and other small molecules, such as those of blood sugar (glucose) and ascorbic acid, can pass through. The blood pressure operates to push part of the water of the blood, together with its burden of small molecules, through these pores into a surrounding capsule.* The
*A seriously ill person or a person in shock may have such low blood pressure that he cannot produce any urine.
glomerular filtrate, with its dilute urine, is produced in amounts of about 180 liters (1) per day, thirty-six times the volume of the blood itself. We cannot stand to lose so much water, and fortunately there is a mechanism to concentrate the urine to the usual volume of one or two 1 a day. As the glomerular filtrate moves along through tubules toward the vessels that carry the urine to the bladder, molecular pumps in the walls of the tubules transfer most of the water back into the bloodstream.* The blood sugar is valuable as a fuel for the body, and it would not be good to lose it. Accord ingly, there are special tubular pumps to pump the glucose molecules back into the blood. There are also special pumps for other important molecules, including those of vitamin G. This is fortunate, because if the process of tubular reabsorption of vita min G did not operate, even a big dose of the vitamin would be nearly completely excreted in an hour or two. In fact, a person who ingests 100 mg per day excretes only about 10 mg in the urine. As discussed in Chapter 7, the necessity of conserving our supply of ascorbic acid arose when our ancestors lost the ability to synthesize it and we were required to depend on what we could obtain in our food. We have developed the mechanism of tubular reabsorption to such an extent that it works nearly perfectly (pumping 99.5 percent of the ascorbate in the glomerular filtrate back into the bloodstream) until it reaches the limit of its pumping capacity. This limit is reached when the concentration in the blood plasma equals about 14 mg per liter, corresponding to a daily intake of about 140 mg. On the one hand, when the discovery was made that at higher intakes than 140 mg per day a greatly increased amount of vitamin G is excreted in the urine, the idea developed that at 140 mg per day the tissues of the body are saturated with the vitamin and are beginning to reject any additional amount. Although this idea is false, it continues to be advanced in the medical and nutritional literature, and the intake of 140 mg per day, corre sponding to the so-called tissue saturation, is considered to be an upper limit to the amount of vitamin G required for “ordinary good health.” An argument similar to those developed in Chapter 9, on the other hand, leads us to the conclusion that this intake, at which the tubular pumps reach their capacity, is a lower limit to the optimum intake (Pauling, 1974). Let us compare a tubular pump for ascorbic acid that pumps until the
*The process of concentrating the urine is regulated by the antidiuretic hormone, which is secreted by the pituitary gland. Some people develop a rather rare illness, diabetes insipidus, involving an insufficient output of this hormone; their urine volume may reach 40 liters per day, requiring them to drink an equal amount of water.
concentration of ascorbic acid in the blood is 14 mg per liter with one that operates only until concentration is 13 mg per liter. The second pump is 7 percent smaller than the first and requires 7 percent less energy, which is provided by the food that we burn as fuel, for its operation. The smaller pump would accordingly be less of a burden to us than the larger one. Then why should we have developed the larger pump? The answer surely is that we need the larger pump to conserve the extra 7 percent of vitamin C. Hence the limit to which tubular reabsorption has been developed repre sents a lower limit to the optimum intake of vitamin G. This lower limit is more than twice the Recommended Daily Allowance (RDA) set by the Food and Nutrition Board. If a large amount of vitamin G is taken, 62 percent of the amount that enters the bloodstream is excreted in the urine, so that only about 38 per cent remains in the body to carry on its valuable functions. It is, however, good to have vitamin G in the urine. It protects against urinary infections and also against cancer of the bladder, as will be shown in Chapter 20. Moreover, that fraction of a large dose of vitamin G taken by mouth that remains in the intestines has value. DeCosse and his coworkers studied the effect of 3 g per day of ascorbic acid in controlling the growth of adeno matous polyps of the rectum in people who have inherited the tendency to develop them (1975). This polyposis is serious because the polyps usually develop into a malignant cancer. In a group of eight patients, the polyps regressed completely in two and partially in three. The appearance of vitamin G in the urine has been used by nutritional authorities as an argument against a high intake. Dr. Fredrick J. Stare in his book Eating for Good Health (1969) states that 60 mg or 70 mg per day is enough: “An extra amount of the vitamin cannot be stored in the body and is simply excreted. You don’t need vitamin-G pills under normal cir cumstances.” These statements are repeated by him in his latest book Panic in the Pantry (Whelan and Stare, 1975). The statements are not true. The observations that have been made on the concentration of ascorbate in the blood plasma corresponding to the capacity of the mechanism of tubular reabsorption in different people give some information about bio chemical individuality with respect to vitamin C. In one study, with nine teen subjects, the capacity varied between 10 mg and 20 mg per liter (Friedman, Sherry, and Ralli, 1940). Similar variation has been found by other investigators. Ascorbic acid is present in the various body fluids and organs, especially the leukocytes and the blood. Its concentration in the brain is also high. When a person with an insufficient supply of ascorbic acid ingests a quan tity of it, it moves very rapidly from the blood serum into the leukocytes, other cells, and organs such as the spleen. The amount remaining in the
blood serum may be so small, less than the capacity of the mechanism of tubular reabsorption, that very little is eliminated in the urine. A test was developed long ago (Harris and Ray, 1935) to show the avidity with which the tissues remove ascorbic acid from the blood serum. This test, called a loading test, involves giving the subject a certain amount of vitamin C by mouth or by injection, collecting the urine for the following six hours, and analyzing it for ascorbic acid. If an oral dose of about 1 g is given, most people whose blood serum is not depleted of the vitamin elimi nate about 20 to 25 percent of it in the urine in six hours. A person who eliminates a smaller fraction of the ingested ascorbic acid may do so either because he or she has been living on a diet containing an insufficient quantity of the vitamin, such that the tissues are depleted, or because some biochemical abnormality of his or her body operates to re move ascorbate from the blood serum very rapidly, perhaps by converting it rapidly into other substances. It was reported by VanderKamp in 1966 that patients with chronic schizophrenia required a loading dose of ascorbic acid about ten times greater than that required by other persons to cause the appearance of a certain amount in the urine. This observation was verified by Herjanic and Moss-Herjanic (1967). The results of another loading test are shown in the illustration on page 89 (Pauling and others, Chapter 2 in Hawkins and Pauling, 1973). In this study forty-four patients recently hospitalized with acute schizophrenia and forty-four other subjects were given 1.76 grams of ascorbic acid by mouth, and the fraction excreted in the urine in six hours was measured. There was a twentyfold individual variation in this fraction, from 2 percent to 40 percent, with the schizophrenic patients excreting only about 60 percent as much as the others. This variation is probably partly nutritional and partly genetic in origin. The distribution functions suggest that there are three kinds of human beings with respect to their handling of ascorbic acid, the low excretors, the medium excretors, and the high excretors. This idea has not, however, been thoroughly tested as yet. Some of the subjects in this study were given 1.76 g of ascorbic acid every day for eight days, and the fraction excreted in the six hours after the last dose was determined. Of sixteen low excretors (less than 17 percent ex creted), eight had moved out of the low-excretor class, whereas the excre tion of the other eight remained low. This observation suggests that these persons have an abnormal way of handling their ingested vitamin G. They might require much larger intake to be in good health. Several serious genetic diseases, such as phenylketonuria, galactosemia, and methylmalonicaciduria are discussed in Chapter 11. Of the many such diseases now known, some can be controlled by a large intake of an appro-
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Vitamin C and schizophrenia In a 1973 study, forty-four patients hospitalized with acute schizophrenia and forty-four Stanford University students took a 1.76-gram dose of ascorbic acid (vitamin C) by mouth. Researchers measured the fraction of the dose excreted in the urine over the next six hours. Many of the students (upper curve) eliminated about 25 percent of the ascorbic acid, a somewhat smaller group eliminated about 20 percent, and some of the students eliminated a still smaller amount. The lower curve, for the schizophrenic patients, seems to show three similar groups, with the two peaks shifted to the left, indicating elimination of smaller amounts of ascorbic acid, and with a larger fraction of the patients eliminating only a small amount of the vitamin. The 17 percent line divides low excretors from high excretors.
priate vitamin. It is harder to recognize a mild genetic disease than a seri ous one, but the mild genetic diseases may in the aggregate cause more suffering than the serious ones, because so many more people suffer from them. It is likely that many of the low excretors of ascorbic acid shown in the illustration above have a genetic defect such that a low intake of vitamin C is more damaging to them than to other people. For them a larger intake of the vitamin may be essential if they are to avoid a short and miserable life. At the present time it is very difficult to determine the nutritional needs of an individual person except by trial of various intakes, but we may hope that reliable clinical tests that show the individual needs will be devel oped before long.
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Orthomolecular Medicine Defined
I believe that in general the treatment of disease by the use of substances, such as ascorbic acid, that are normally present in the human body and are required for life is to be preferred to treatment by the use of powerful synthetic substances or plant products, which may, and usually do, have undesirable side effects. Such substances as vitamin C and most of the other vitamins are remarkable for their low toxicity and absence of side effects when taken in amounts larger than those usually available in the diet. I have coined the term orthomolecular medicine for the preservation of good health and the treatment of disease by varying the concentrations in the human body of substances that are normally present in the body and are required for health (Pauling 1968B). Dr. Bernard Rimland (1979) has emphasized my point by suggesting that conventional medicine, which uses drugs, be called toximolecular medicine. Death by starvation, kwashiorkor, beriberi, scurvy, or any other defi ciency disease can be averted by providing an adequate daily intake of carbohydrates, essential fats, proteins (including the essential amino acids), essential minerals, and thiamine, ascorbic acid, and other vitamins. To achieve the best of health, the rate of intake of essential foods should be such as to establish and maintain the optimum concentrations of essential molecules, such as those of ascorbic acid.
An example of orthomolecular medicine is the treatment of diabetes mellitus by the injection of insulin. Diabetes mellitus is a hereditary dis ease, usually caused by a recessive gene. The hereditary defect results in a deficient production by the pancreas of the hormone insulin. The primary action of insulin is to cause an increase in the rate of extraction of glucose from the blood into the cells, where it can be metabolized. In the absence of insulin the concentration of glucose in the blood of the patient becomes much greater than normal, resulting in manifestations of the disease. Insulin extracted from cattle pancreas or pig pancreas differs only slightly in its molecular structure from human insulin, and it has essen tially the same physiological activity. The injection of cattle insulin or pig insulin in a human is essentially the provision of the normal concentration of insulin in the body of the patient; it permits the metabolism of glucose to take place at the normal rate and thus serves to counteract the abnormality resulting from the genetic defect. Insulin therapy is accordingly an example of orthomolecular therapy. Its major disadvantage is that the insulin can only be introduced into the bloodstream by injection. Another example of orthomolecular treatment of this disease, if it is not serious, is by adjusting the diet, regulating the intake of sugar, especially, in such a way as to keep the glucose concentration in the blood within the normal limits. A third example is increasing intake of vitamin C to decrease the need for insulin. Dice and Daniel (1973) reported from the study of one diabetic subject that for each gram of L-ascorbic acid taken by mouth the amount of insulin required could be reduced by two units. A fourth way to control diabetes, by using so-called oral insulin, a drug taken by mouth, does not constitute an example of orthomolecular medi cine, because oral insulin is a synthetic drug, foreign to the human body, which may have undesirable side effects. Another disease that is treated by orthomolecular methods is phenyl ketonuria. It results from a genetic defect that leads to a decreased amount or effectiveness of an enzyme in the liver that in normal persons catalyzes the oxidation of one amino acid, phenylalanine, to another, tyrosine. Ordi nary proteins contain several percent of phenylalanine, providing a much larger amount of this amino acid than a person needs. The concentration of phenylalanine in the blood and other body fluids of the patient becomes abnormally high, if he or she is on a normal diet, causing mental deficiency, severe eczema, and other manifestations. The disease can be controlled by a diet, beginning in infancy, that contains a smaller amount of phenylalanine than is present in ordinary foods. In this way the concentration of phenylal anine in the blood and other body fluids is kept to approximately the normal level, and the manifestations of the disease do not appear.
A somewhat similar disease, which can also be controlled by ortho molecular methods, is galactosemia. It involves the failure to manufacture an enzyme that carries out the metabolism of galactose, which is a part of milk sugar (lactose). The disease manifests itself in mental retardation, cataracts, cirrhosis of the liver and spleen, and nutritional failure. These manifestations are averted by placing the infant on a diet free of milk sugar, with the result that the concentration of galactose in the blood does not exceed the normal limit. A conceivable sort of orthomolecular therapy for phenylketonuria or other hereditary diseases involving a defective gene would be to introduce the gene (molecules of deoxyribonucleic acid, or DNA), separated from the tissues of another person, into the cells of the person suffering from the disease. For example, some molecules of the gene that directs the synthesis of the enzyme that catalyzes the oxidation of phenylalanine to tyrosine could be separated from liver cells of a normal human being and introduced into the liver cells of a person with phenylketonuria. This sort of change in the genetic character of an organism has been carried out for microorga nisms but not yet for human beings, and it is not likely that it will become an important way of controlling genetic defects until many decades have passed. Another possible method of orthomolecular therapy for phenylketonuria, resembling the use of insulin in controlling diabetes, would be the injection of the active enzyme. There are two reasons why this treatment has not been developed. First, although it is known that the enzyme is present in the liver of animals, including humans, it has not yet been isolated in purified form. Second, the natural mechanism of immunity, which involves the action of antibodies against proteins foreign to the species, would oper ate to destroy the enzyme prepared from the liver of animals of another species. This mechanism in general prevents the use of enzymes or other proteins from animals other than humans in the treatment of diseases of human beings. There is still another possible type of orthomolecular therapy. The mole cules of many enzymes consist of two parts: the pure protein part, called the apoenzyme, and a nonprotein part, called the coenzyme. The active en zyme, called the holoenzyme, is the apoenzyme with the coenzyme attached to it. Often the coenzyme is a vitamin molecule or a closely related mole cule. It is known, for example, that a number of different enzymes in the human body, catalyzing different chemical reactions, have thiamine diphos phate, a derivative of thiamine (vitamin Bl), as coenzyme. In some cases of genetic disease the enzyme is not absent but is present with diminished activity. One way in which the defective gene can operate
is to produce an apoenzyme with abnormal structure, such that it does not combine readily with the coenzyme to form the active enzyme. Under ordi nary physiological conditions, with the normal concentration of coenzyme, perhaps only 1 percent of the abnormal apoenzyme has combined with the coenzyme. According to the principles of chemical equilibrium, a larger amount of the abnormal apoenzyme could be made to combine with the coenzyme by increasing the concentration of the coenzyme in the body fluids. If the concentration were to be increased one hundred times, most of the apoenzyme molecules might combine with the coenzyme, to give essen tially the normal amount of active enzyme. There is accordingly the possibility that the disease could be kept under control by the ingestion by the patient of a very large amount of the vitamin that serves as a coenzyme. This sort of orthomolecular therapy, involving only a substance normally present in the human body (the vitamin), is, in my opinion, the preferable therapy. An example of a disease that sometimes is controlled in this way is the disease methylmalonicaciduria. Patients with this disease are deficient in the active enzyme that catalyzes the conversion of a simple substance, methylamalonic acid, to succinic acid. It is known that cyanocobalamin (vitamin B12) serves as the coenzyme for this reaction. It is found that the provision of very large amounts of vitamin B12, giving concentrations about a thousand times the normal concentration, causes the reaction to proceed at the normal rate for many patients. The use of very large amounts of vitamins in the control of disease, called megavitamin therapy, is an important procedure in orthomolecular medi cine. It is my opinion that in the course of time it will be found possible to control hundreds of diseases by megavitamin therapy. For example, Abram Hoffer and Humphry Osmond demonstrated, as was mentioned in Chapter 3, that many patients with schizophrenia are benefitted by megavitamin therapy (Hoffer, 1962; Hoffer and Osmond, 1966). Their treatment in cludes the administration of nicotinic acid (niacin) or nicotinamide (niacin amide) in amounts of 3 grams (g) to 18 g per day, together with 3 g to 18 g per day of ascorbic acid, and good amounts of other vitamins (Hawkins and Pauling, 1973; Pauling, 1974b). It is usually thought that a drug that is claimed to be a cure for many different diseases cannot have any value against any one of them. Yet there is evidence, summarized in this book, that a large intake of vitamin C helps to control a great many diseases: not only the common cold and the flu, but also other viral and bacterial diseases, such as hepatitis, and also quite unrelated diseases, including schizophrenia, cardiovascular disease, and cancer. There is a reason for this difference between vitamin C and ordi nary drugs. On the one hand, most drugs are powerful substances that
interact in a specific way with one kind of molecule or tissue or agent of disease in the body so as to help to control a particular disease. The sub stance may, however, interact in a harmful way with other parts of the body, thus producing the side effects that make drugs dangerous. Vitamin C, on the other hand, is a normal constituent of the body, re quired for life. It is involved in essentially all of the biochemical reactions that take place in the body and in all of the body’s protective mechanisms. With the ordinary intake of vitamin C these reactions and mechanisms do not operate efficiently; the person ingesting only the 60-milligram (mg) Recommended Dietary Allowance (RDA) is in what might be called ordi nary poor health—what the physicians and nutritionists call “ordinary good health.” The optimum intake of vitamin C, together with other health measures, can provide really good health, with increased protection against all diseases. That increase in protection is secured, as we shall see in Chap ter 12, by strengthening the immune system, a process in which vitamin C plays a crucial role. The optimum intake is necessarily large. When that lesson is learned and practiced, the protection provided by vitamin C may well be the most important of all methods of orthomolecular medicine. While less is known about the other vitamins, there is no doubt that, used in the proper amounts, they also can be of great value. In the chapters that follow, we shall consider the ways in which supple mental intake of the vitamins can prevent many diseases, sustain the body’s resistance to the stress and damage of illness, and provide effective therapy in a manner preferable to that by drugs and, when necessary, in association with drugs and other conventional methods of treatment. If no mention is made of some disease, readers should not conclude that improved nutrition is not helpful. For many diseases and medical problems there are reports about the apparent effectiveness of a high intake of one vitamin or the use of some other orthomolecular substance. Reports of this sort are usually not published in the standard medical journals, but they may be found, for example, in Prevention magazine. The reports may not be reliable; the writer may have reached the unjustified conclusion that the improvement in health that occurred when he or she increased the intake of a vitamin was caused by that increase, when in fact it was just a coinci dence. If the same report is made many times, however, it may be given some credence, even though medical investigators have, because of their lack of interest in vitamins, failed to carry out any definitive studies. It is especially important to try improved nutrition in the effort to control “incurable” diseases, as was pointed out by Cheraskin and Ringsdorf (1971), who gave multiple sclerosis as one of their examples. A recommen dation to try a drug when there is not strong evidence for its probable effectiveness should not be made, of course, because drugs are dangerous.
It is fortunate that vitamins are so lacking in toxicity and harmful side effects that this caveat does not apply to them. I remember a young physician who came to my home thirteen years ago and said, “Dr. Pauling, you saved my life. I was dying of chronic hepatitis, but I heard about high-dose vitamin C, and it has cured me.” Since then good studies of the value of vitamin C in the prevention and treatment of hepatitis have been made (Chapter 14), but there are other diseases for which such studies have not yet been carried out. One of these is amyotrophic lateral sclerosis (ALS), brought to public attention as the disease of which the famous Yankee outfielder Lou Gehrig died. In August 1985 I received a letter from a physician who described himself in the following way: “I am a medical ‘miracle.’ I’ve suffered from ALS for over eight years, with loss of function pretty well localized, and no spreading. I take between 12 and 20 grams of ascorbic acid every day, avoid fats and greases, and take at least 200 mg of a full B complex every day.” The acceptance of orthomolecular medicine would surely help somewhat to solve one of the great present-day problems, the high cost of health care. In 1965 the total public and private spending on health care in the United States was $40 billion; in twenty years it has increased tenfold, to $400 billion (Report of the Department of Health and Human Services, 1985). The increasing cost of medical care, amplified by inflation, accounted for 76 percent of this increase and population growth for 11 percent. The cost of health care was 6 percent of the gross national product in 1965 and 11 percent in 1985. This increase reflects both the rapid rise in charges for medical services (after corrections for inflation) and the increasing avail ability of expensive high-technology methods of diagnosis and treatment. A recent discussion (Atkins et al., 1985) of high-tech cardiology mentioned some of the new technologies now in use: telemetry units for monitoring arrythmias, diagnostic cardiac catheterization, invasive electrophysiologic assessments, permanent artificial pacemakers, electrocardiography and Doppler studies for assessing cardiac function, nuclear imaging, open-heart surgery, and heart transplantation. The discussion went on to new technol ogies soon to be applied: magnetic resonance imaging; high-speed comput erized tomography scanning of the heart; and implantable “cardioverters” that automatically correct potentially lethal arrhythmias. Additional tech nologies include implantable defibrillators in high-risk patients to restore the cardiac beat after arrest, artificial heart implantation, and laser angioscopy to visualize atherosclerotic coronary plaques directly and to guide the “recanalizing” of obstructive narrowing. Among the problems associated with this development are the very high cost and the pressures from both patients and physicians to make sometimes inappropriate use of the techniques. Dr. George A. Beller, of the Univer-
sity of Virginia, listed ten forces that operate against cost containment in cardiology: First, physicians are motivated to provide the highest quality of care possible, regardless of cost. Second, most physicians are still on a feefor-service basis. Third, physicians are paid the highest premium for per forming technologically sophisticated procedures. Fourth, physicians are likely to try to convince hospital administrators to acquire the latest innova tions. Fifth, the administrators are under pressure to increase the hospital’s share of patients in the face of competition and therefore view it desirable to acquire these technologies. Sixth, patients are attracted to hospitals offering the latest equipment, services, and modern technologies. Seventh, suppliers of high-tech goods and services have an interest in continued growth. Eighth, some physicians feel pressured to order tests that they know are probably unnecessary because a consultant has written them as suggestions in the patient’s chart. If the patient does not do well, failure to follow the consultant’s advice could be considered negligent in court. The fear of a malpractice suit is certainly an inhibiting factor in cost containment. Ninth, it is often difficult to distinguish tests that are undertaken for clinical re search from tests that are necessary for clinical management. Tenth, the need for an ultimate diagnosis has been a prevailing factor in cardiologic practice. Beller also pointed out that another force is our society’s special sympa thy for those who are suffering. He quoted Gregory Pence of the University of Alabama as saying, “Medical costs are uncontrollable because we lack moral agreement about how to deny medical services. Deciding how to say ‘no,’ and to say it with honesty and integrity, is perhaps the most profound, most difficult moral question our society will face in the coming years.” These are difficult problems. I believe that orthomolecular medicine can contribute to their solution. Vitamins are much less expensive than drugs. The amount of suffering caused to the patient by the treatment should be taken into consideration—a high intake of vitamins improves the state of well-being of the patient and helps to control the unpleasant side effects of some conventional therapies. Finally, if the aim of medical care is not merely to cure sickness but to promote health, then it should be foremost in the physician’s mind that improved nutrition can help the patient signifi cantly in reaching the goal of a good and satisfying life.
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Our bodies are protected from onslaughts from both without and within by our natural protective mechanisms. The most important of these is the immune system. By keeping that system operating as effectively as possible we can make a significant contribution to our own good health. When vitamins were first isolated and investigated half a century ago it was observed that a deficiency in any one of several of them resulted in impairment of the immune system, such as a decrease in the number of leukocytes in the blood and in a decreased resistance to infection. The vitamins required for good immunity are vitamin A, vitamin B12, panto thenic acid, folacin, and vitamin C. These are also the vitamins that seem to strengthen the immune system when they are taken in amounts larger than those usually recommended. The effect on the immune system is greatest for vitamin C. I shall discuss the evidence in this chapter. When we were discussing the immune system in relation to cancer in our book Cancer and Vitamin C (Cameron and Pauling, 1979), Dr. Ewan Cameron and I wrote that the immunological defense system has the diffi cult task of distinguishing foe from friend by first recognizing “nonself’ (the invading vectors of disease, such as bacteria or malignant cells) as distinct from “self’ (the normal cells). Recognition depends upon the evalu ation of differences in molecular structure. For the viral and bacterial vec-
tors of disease these differences are striking, and their recognition is rela tively easily accomplished, whereas for the cancer cells the differences are slight, and the immune mechanisms must be highly competent in order to be effective. As pictured by Lewis Thomas, former president of the Memo rial Sloan-Kettering Cancer Center, the immune system functions as a police force, constantly patrolling the body and checking the cells, keeping an eye open for cells that have become malignant, and, when they have been recognized, destroying them. There is much evidence that vitamin C is essential for the efficient work ing of the immune system. The mechanisms of the immune system involve certain molecules, mainly protein molecules that are present in solution in the body fluids, as well as certain cells. Vitamin C is involved both in the synthesis of many of these molecules and in the production and proper functioning of the cells. Antibodies (also called immunoglobulins) are rather large protein mole cules, each molecule consisting of about fifteen thousand or twenty-five thousand atoms. A human being is able to make about a million different kinds of antibody molecules. Each kind is able to recognize a particular group of atoms, called a haptenic group or hapten, carried in its antigen, a foreign molecule. Most people do not make antibodies that can combine with haptens. Those unfortunate people who do so suffer from a special sort of disease, an “autoimmune” disease; it is possible that lupus erythematosis and glomerular nephritis may be such diseases. The haptenic groups in an antigen stimulate the cells in the body that manufacture the corresponding specific antibodies to divide and to form a clone of a large number of cells. These new cells liberate the specific anti bodies into the blood, where they can combine with the antigenic molecules or cells and mark them for destruction. It has been found that an increased intake of vitamin C leads to the man ufacture of more antibody molecules. Increase in antibodies of types IgG and IgM was reported by Vallance (1977). He studied subjects who for nearly a year were isolated in a British research station in Antarctica, out of contact with any sources of new infection, which, by stimulating immu noglobulin production, would have introduced a disturbing factor. Prinz and his coworkers gave 1 gram (g) of vitamin C to twenty-five healthy male university students and a placebo to twenty similar subjects. After seventyfive days they found that for the vitamin-C subjects there was a significant increase in the serum levels of the immunoglobulins IgA, IgG, and IgM (Prinz et al., 1977, 1980). A similar dependence of the production of anti bodies on the intake of vitamin C has also been observed in guinea pigs, which share our dependence on outside sources for a supply of this vitamin. IgA is the form of antibody that is present in the largest amount (to gether with some IgM) in nasal secretions; it is largely responsible for the
antiviral action of these secretions. All three forms are present in blood and interstitial fluid, IgM in the largest amount. Bacterial cells and malignant cells that have been identified as foreign by the molecules of specific antibodies adhering to them have to be prepared for destruction by combination with some other protein molecules, the com ponents of complement, that are present in the bloodstream. There is some evidence that vitamin C is involved in the synthesis of the Cl-esterase com ponent of complement and that the amount of this important substance increases with increase in the intake of this vitamin. Without this impor tant component of complement the whole complement cascade is inoperable and the “nonselP cells would not be destroyed. There is no doubt that vitamin G is required also in humans for the synthesis of Cl-esterase, be cause this component of complement contains protein molecules that are similar to the molecules of collagen that are known to require vitamin C for their synthesis. After the foreign cells or malignant cells have been identified and marked for destruction they are attacked and destroyed by the phagocytic (cell eating) cells that patrol the body. These phagocytic cells are white cells, leucocytes, in the blood and other body fluids. Leucocytes are found in large numbers in the pus formed in suppurating abscesses or sores, where they have been fighting an infection. Leucocytes that are made in the lymph glands are lymphocytes. They are conveyed in the lymph (a suspension of the cells in a clear yellowish fluid resembling blood plasma) through the lymphatic vessels to the bloodstream. The lymphocytes seem to be the most important of the phagocytic cells in the battles against cancer and other diseases. A malignant tumor is often observed to be infiltrated with lymphocytes, and a high degree of lympho cyte infiltration is now accepted as a reliable indicator of a favorable out come of the disease. Moreover, it has been demonstrated that guinea pigs maintained on very low intakes of vitamin G tolerate skin grafts from other guinea pigs, and that this tolerance is related to their abnormally low lym phocyte ascorbate levels (Kalden and Guthy, 1972). When the guinea pigs are given large amounts of vitamin C the skin grafts are promptly rejected, showing that the immune systems are again functioning. These observations and the well-known fact that leukocytes are phagocytically effective only if they contain a rather large amount of ascorbate led Dr. Ewan Cameron and me to suggest in 1974 that a high intake of vitamin C would permit the lymphocyte part of the defense mechanisms against cancer to function at high efficiency. This prediction has now been confirmed. Working in the National Cancer Institute, Yonemoto and his coworkers (Yonemoto, Chretien, and Fehniger, 1976; Yonemoto, 1979) studied five healthy young men and women, eighteen to thirty years old,
who initially were receiving the ordinary low intake of vitamin C. They took samples of blood, separated the lymphocytes, and measured their rate of blastogenesis (production of new lymphocyte cells by budding) when stimulated by an antigenic foreign substance, phytohemagglutinin. Then they gave each subject 5 g of vitamin C on each of three successive days. The rate of formation of new lymphocytes, as measured by the same test of the separated cells, had nearly doubled (an increase of 83 percent) in a few days, and it remained high for another week. A dose of 10 g per day for three days caused this rate to triple, and a dose of 18 g per day caused it to reach four times the original value. This study leaves little doubt that a high intake of vitamin C by cancer patients increases the effectiveness of the body’s protective mechanism involving lymphocytes and leads to a more favorable prognosis for the patient suffering from cancer or an infectious disease. More extensive studies of this sort are needed to determine the intake of vitamin C, both orally and intravenously, that leads to the maxi mum rate of blastogenesis of lymphocytes. The indication from the work of Yonemoto and his coworkers is that the optimum oral intake may be greater than 18 g per day. Many investigators have reported that an increase in the intake of vita min C by either normal subjects or patients with certain diseases leads to increased motility of leukocytes and their more rapid movement to the site of an infection (Anderson, 1981, 1982; Panush et al., 1982). There is fur ther evidence that when they arrive, vitamin C increases their capacity for phagocytosis. This is the process in which leucocytes surround and destroy bacterial cells or malignant cells that have been identified as foreign and marked for destruction; the individual leucocyte surrounds and engulfs the foreign cell. Vitamin C is required for this process. It was discovered long ago that leucocytes are not phagocytically effective if they do not contain enough ascorbate (Cottingham and Mills, 1943). A recent study (Hume and Weyers, 1973) has shown that persons on an ordinary Scottish diet and in good health had a little more ascorbate in their leucocytes than the amount needed for phagocytic activity but the amount dropped to half this value on the first day after they had contracted colds, and it stayed low for several days, rendering them susceptible to secondary bacterial infections. An intake of 250 milligrams (mg) of ascorbic acid per day was not enough to keep the amount of ascorbate in the leucocytes up to the level required for effective phagocytosis, but 1 g per day plus 6 g per day beginning at the onset of the cold was found to be enough to keep this important protective mechanism operating. I conclude from this study that the prophylactic intake of ascorbic acid, the dose taken regularly to preserve good health and provide protection against disease, almost certainly should be more than 250 mg per day for
most people. Other considerations led me to suggest the range 250 mg to 4000 mg, or even 10,000 mg, for recommended daily intake for most people (Pauling, 1974c). Such an intake should decrease the chance of contracting the common cold or influenza and, if a viral infection is contracted, should prevent a secondary bacterial infection from developing. Irwin Stone (1972) has described vitamin C in relation to bacterial dis eases in the following words: 1. It is bactericidal or bacteriostatic and will kill or prevent the growth of the pathogenic organisms.* 2. It detoxicates and renders harmless the bacterial toxins and poisons. 3. It controls and maintains phagocytosis. 4. It is harmless and nontoxic and can be administered in the large doses needed to accomplish the above effects without danger to the patient. Another, more recently recognized, agent in the immune system is the interferons. These are proteins with antiviral activity, which are produced by cells infected by a virus and possibly also by malignant cells. Spreading to neighboring cells, the interferons change them in such a way as to enable them to resist infection. There is some evidence that interferons help in the effort by the human body to control a developing cold or other infection or cancer. Different kinds of interferon are synthesized by different animal species. Human beings make about twenty different kinds of interferon molecules, with somewhat different activities, in different cells in the body. Interferon has attracted lively interest because very few drugs have any effectiveness against viral infections and cancer. Since interferons are proteins, animal interferons act as antigens in hu man beings and cannot be injected without sensitizing the person in such a way that further injections would cause serious allergic reactions. Human interferons, made from human leucocytes in cell culture, are now avail able, but at a rather high price. Studies have indicated that injections of these substances have some value in treating cancer and infectious diseases (Borden, 1984). The suggestion that an increased intake of vitamin C would lead to the production of larger amounts of the interferons (Pauling, 1970) has been verified. Until more evidence becomes available about the value of injec*Evidence for this statement will be considered in Chapter 14.
tions of human interferon, we may be wise to follow the advice of Cameron: “Take more vitamin C and make your own interferon!” The prostaglandins are small molecules (lipids, related to fats) that play a potent, central role in the functioning of the human body. Acting as hormones, they are involved in regulation of the heart beat, the flow of blood, the damage done to cells by drugs, and the responses of the immune system. Their isolation and characterization have occurred mainly since 1960, with many discoveries made since 1970. The formula of prosta glandin PGE1 is C2oH 3405, and the other prostaglandins have the same or closely similar formulas.
Whenever any tissue is disturbed or damaged it releases prostaglandins (Vane, 1971). The prostaglandins, especially PGE2 and PGF2-alpha, are involved with other substances in producing inflammation of the tissues— redness, swelling, pain, tenderness, and heat—resulting from increased flow of blood and the movement of leucocytes and other cells and substances to the region in response to the hormones. As we shall see in the compari son of drugs and vitamins in Chapter 26, the function of the prostaglandins in inflammation is controlled to some extent by aspirin. In 1978 Horrobin reported that vitamin C inhibits the synthesis of PGE2 and PGF2-alpha, and in this way the vitamin also exerts a considerable anti-inflammatory action (Horrobin, 1978). He reported, however, that whereas aspirin in hibits the synthesis of PGE1, vitamin C increases the amount synthesized (Horrobin, Oka, and Manku, 1979). The prostaglandin PGE1 is involved in the formation of lymphocytes and plays a major part in the regulation of immune responses. Accordingly the effect of vitamin C in stimulating the production of PGE1 is an additional way in which the intake of the opti mum amount of vitamin C strengthens the immune system and contributes to the maintenance of better health.
13T h e
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Most people catch several colds each year, usually in the fall, winter, and spring. When you catch a cold, after you have been exposed to cold viruses being spread by some other person, you may sneeze, feel a chill and scratchiness of the throat, develop a runny nose or stopped-up nose, and show other signs of the viral infection. Later, as the cold develops, you may feel rather miserable for two or three days. At this time it is usually wise to stay at home and rest in bed—for your own well-being and to spare your family and your colleagues the risk of exposure to your cold. After a week or ten days you have usually recovered. Having a cold two or three times a year is not pleasant. What is worse, the cold may be attended by serious complications—bronchitis, sinus infec tion, infection of the middle ear, infection of the mastoid bone (mastoiditis), meningitis, bronchopneumonia or lobar pneumonia, or exacerbation of some other disease, such as arthritis or kidney disease or heart disease. The common cold (acute coryza) is an inflammation of the upper respi ratory tract caused by infection with a virus.* This infection alters the *A discussion of the many viruses that can cause the common cold is given in the book The
Common Cold , by Sir Christopher Andrewes, 1965.
physiology of the mucous membrane of the nose, the perinasal sinuses, and the throat. The common cold occurs more often than all other diseases combined. This infection does not occur, however, in small isolated commu nities; exposure to the virus, carried by persons from the outside, is needed. Thus, the Norwegian island of Spitsbergen used to be isolated during seven months of the year. The 507 residents of the principal town of the island, Longyear, were nearly free of colds through the cold winter, with only four colds recorded in three months. Then within two weeks after the arrival of the first ship some 200 of the residents had become ill with colds (Paul and Freese, 1933). Development of a cold after exposure to the virus is determined to some extent by the state of health of the person and by environmental factors. Fatigue, chilling of the body, wearing of wet clothing and wet shoes, and the presence of irritating substances in the air are traditionally cited as preludes to a cold. Experimental studies indicate, however, that these fac tors are not so important as is generally believed (Andrewes, 1965; Debre and Celers, 1970, page 539). The period of incubation, between exposure and the manifestation of symptoms, is usually two or three days. The first symptoms are the familiar ones cited in the first paragraph of this chapter. Headache, general malaise (an indefinite feeling of uneasiness or discomfort), and chills (a sensation of coldness attended with convulsive shaking of the body, pinched face, pale skin, and blue lips) often attend the progress of the cold. A slight increase in temperature, usually to not over 101 °F (38.3°C), may occur. The mu cous membranes of the nose and pharynx are swollen. One nostril or both nostrils may be blocked by the thickened secretions. The skin around the nostrils may become sore, and cold sores (caused by the virus Herpes simplex) may develop on the lips. The customary treatment for the common cold includes resting in bed, drinking fruit juice or water, ingesting a simple and nutritious diet, pre venting irritants such as tobacco smoke from entering the respiratory tract, and alleviating the symptoms to some extent by the use of aspirin, phenacetin, antihistamines, and other drugs (see Chapter 26). After some days the tissues of the nose and throat, weakened by the virus infection, are often invaded by bacteria. This secondary infection may cause the nasal secretions to become purulent (to contain pus). Also, the secondary infec tion may spread to the sinuses, the middle ears, the tonsils, the pharynx, the larynx, the trachea, the bronchi, and the lungs. As mentioned above, mas toiditis, pneumonia, meningitis, and other serious infections may follow. Control of the common cold thus would lead to a decrease in the incidence of more serious diseases. Not everyone is susceptible to infection with the common cold. Most investigators have noted that an appreciable proportion of the population, 6
to 10 percent, never have colds. This fact provides justification for hope that a significant decrease in the number of colds can be achieved through in crease in the resistance of individuals to viral infection. It is likely that the ability of 6 to 10 percent of the population to avoid colds is the result of their natural powers of resistance. Like other physiological properties, the resistance of individuals to viral infection probably can be represented by a distribution curve that has approximately the normal bell shape. The 6 to 10 percent of the population that are resistant to colds presumably corre spond to the tail end of the curve, those people with the largest natural powers of resisting viral infections. If in some way the natural resistance of the whole population could be shifted upward, a larger percentage of the population would lie in the range corresponding to complete resistance to the infection and would never have colds. This argument indicates strongly that a study of the factors involved in the natural resistance to viral infec tion, such as nutritional factors, could lead to a significant decrease in the susceptibility of the population as a whole to the common cold. Consider ing, along with this possibility, that the common cold disappears in iso lated communities like Spitsbergen, I am moved to declare again my belief that the nuisance and menace of the common cold might be stamped out entirely. I have made a rough estimate of the significance of the common cold, measured in dollars. Let us assume that the average loss of time because of serious illness with the common cold is seven days per person per year. The person suffering from a cold or series of colds during the year might stay away from work, or might have a decreased effectiveness, or might be sufficiently ill and miserable to feel that the seven days are wasted. In any event, a measure of the damage done by the common cold might be roughly taken as the person’s loss of productivity and income for the seven days during the year when he or she is most seriously ill. The personal income of the people of the United States is about 53,000 billion per year (1985). The income per week is this quantity divided by fifty-two. We may accordingly be justified in saying that the damage done by the common cold to the people of the United States each year can be described roughly as corre sponding to a monetary loss of $60 billion per year * This corresponds to a loss in income or its equivalent in well-being of about $250 per year per person. It is easy to understand why the people of the United States spend hundreds of millions of dollars per year on cold medicines, despite their limited effectiveness. *A smaller estimate, $5 billion per year, was given by Fabricant and Conklin in their book The Dangerous C o l d 1965. The increase is the result of population growth and monetary inflation.
It has been known for more than twenty years that most people can keep from having colds, or, if a cold develops, can suppress most of its disagree able manifestations, by the proper use of vitamin C. There is no need for you to be made miserable by the common cold. In the medical literature, nonetheless, it continues to be said that no clearly effective method of treatment of the common cold has been devel oped. The various drugs that are prescribed or recommended have some value in making the patient more comfortable, by giving relief from some of the more distressing symptoms, but they have little effect on the duration of the cold. The fact that doctors have not had a good way of preventing and treating the common cold has been the subject of many jokes. The doctor says to the patient, “You have a cold. I don’t know how to treat it, but if it develops into pneumonia, come to see me because I can cure pneumonia.” There is another joke that appeared after the first edition of my book Vitamin C and the Common Cold was published in 1970. The doctor says to the patient, “You are suffering from an overdose of vitamin C, so I shall give you an injection of cold viruses to counteract it.” A great many people have reported to me that their lives were changed by reading my book. Whereas during previous years they had suffered from many colds, their increased intake of vitamin G had been effective in pro viding complete protection against this disease. Other people, however, re ported that following my recommendations did not keep them from devel oping colds that were just about as serious as those that they had caught earlier. The continued study of this problem has led me to conclude that human beings, with their biochemical individuality, differ quite a bit from one another in the amount of vitamin G required to provide protection against the common cold. For some people the achievement of really good health and protection against cold viruses requires the intake of a far larger amount of vitamin C than was recommended in my book. I now believe that every person can protect himself or herself against the common cold, or, if a cold begins to develop, can make its symptoms far less serious than they would be otherwise, by taking the amount of vitamin C that is appro priate to him or her. If you have established your optimum nutritional intake of vitamin C, you will find yourself going through the common-cold season without a cold. This statement may, in fact, be put the other way around. If you go through the season cold-free, you have probably found your optimum nu tritional intake of vitamin C. Your heightened resistance may nonetheless be overridden. When you feel the first symptoms of a cold coming on, you should increase your intake of vitamin G at once to the therapeutic level. In my own experience, this means taking 1 gram (g) or more of vitamin C per hour throughout the
waking hours of the day. Cold symptoms are usually suppressed at once, and they remain so if the therapeutic dose is maintained for the duration of what would otherwise have been the cold. The one discomfort in this regi men may be a looseness of the bowels in the first few days. My simple prescription remains, of course, heresy to orthodox nutrition ists and most practitioners of medicine. I was on a televison show, with David Frost, some years ago with the nutrition authority Dr. Fredrick J. Stare, Mademoiselle's “Big Name in nutrition,” as my fellow guest. Stare and I made somewhat different statements about vitamin C and its value, and the hour-long program came nearly to its end. Finally, Stare said, “I know that Dr. Pauling’s method of preventing the common cold is no good, because I tried it, and it didn’t work.” I started to ask a question about how he had tried it, but Frost said, “Gentlemen, I am sorry that our time is up, and I thank you for having been on the program.” Then, as we were walking away, Stare turned to me and said “Of course, I didn’t use the astronomical amount that you recommend.” This story has some bearing on the question of why physicians on the whole have not been recommending the use of vitamin C to their patients to help prevent the common cold and other diseases. Although physicians, as part of their training, are taught that the dosage of a drug that is prescribed for the patient must be very carefully determined and controlled, they seem to have difficulty in remembering that the same principle applies to the vitamins. Stare probably could have prevented his cold from developing if he had taken the “astronomical amount” that I recommend. I believe that every cold or other illness that a person suffers from dam ages his or her body in a permanent way to some extent, and shortens his or her life expectancy. Using vitamin C to prevent colds may slow down the aging process. This is part of the contribution that results from following the regimen that I urge in this book for the prolongation of life and espe cially of the period of well-being, during which life is really enjoyed. The answer to the apparent contradiction between the opinions ex pressed by authorities in nutrition and my own experience is a simple one. Vitamin C has only rather small value in providing protection against the common cold when it is taken in small amounts, but it has great value when it is taken in large amounts. Most of the studies referred to in the editorial article in the August 1967 issue of Nutrition Reviews, mentioned in Chap ter 3, involved giving small amounts of ascorbic acid to the subjects, usually 200 milligrams (mg) per day. But even these studies indicate that such small amounts have some protective value, not very great, against the com mon cold. The amount of protection increases with increase in the amount of ingested vitamin C and becomes nearly complete with 10 g to 40 g per day taken at the immediate onset of the cold.
The study of vitamin C in relation to the common cold began only a few years after the vitamin was identified as ascorbic acid. Dr. Roger Korbsch of St. Elisabeth Hospital, Oberhausen, Germany, was one of the first to publish an account of such a study, in 1938. The fact that ascorbic acid has been reported to be effective against several diseases, including gastritis and stomach ulcers, suggested that he try it in treating acute rhinitis and colds. In 1936 he found that oral doses of up to 1 g per day were of value against rhinorrhea, acute rhinitis, and secondary rhinitis and accompanying mani festations of illness, such as headache. He then found that the injection of 250 or 500 mg of ascorbic acid on the first day of a common cold almost always led to the immediate disappearance of all the signs and symptoms of the cold, with a similar injection sometimes needed on the second day. He stated that ascorbic acid is far superior to other cold medicines, such as aminopyrine, and is without danger, in that there is no evidence that there are serious side effects, even with large doses. A trial was then made in Germany (Ertel, 1941) in which 357 million daily doses of vitamin C were distributed among 3.7 million pregnant women, nursing mothers, suckling infants, and schoolchildren. Ertel re ported that the recipients of the vitamin C enjoyed better health, in several different respects, than the corresponding control populations. The only quantitative information given by him is that with one group of schoolchil dren for which good statistical data were collected the amount of illness with respiratory infections was 20 percent less than the year before. In 1942 Glazebrook and Thomson reported the results of a study carried out in an institution where there were about 1500 students, whose ages ranged from fifteen to twenty years. The food was poorly prepared, being kept hot for two hours or more before serving, and the total intake of ascorbic acid was determined to be only about 5 to 15 mg per student per day. Some of the students (335) were given additional ascorbic acid, 200 mg per day, for a period of six months, and the others (1100) were kept as controls. The incidence of colds and tonsillitis was 14 percent less among the students given ascorbic acid than among the controls. The number of serious cases of colds or tonsillitis requiring admission to sick quarters was 25 percent less for the students receiving ascorbic acid than for the controls. This difference has high statistical significance (only 1 percent probability in a uniform population). The average number of days of hospitalization per student because of infection (common cold, tonsillitis, acute rheuma tism, pneumonia) was 2.5 days for the students receiving ascorbic acid and 5.0 days for the controls. These were 17 cases of pneumonia and 16 cases of acute rheumatism among the 1100 controls, and no case of either disease among the 335 students receiving ascorbic acid. The probability of such a great difference in two samples of a uniform population is so small (less than 0.3 percent) as to indicate very strongly that vitamin C has value in
providing protection against these serious infectious diseases, as well as against the common cold and tonsillitis. A study made famous by detractors of my prescription of vitamin C is that of Cowan, Diehl and Baker, which I cited in Chapter 3. The main result of the study is that the students who received the placebo lost an average of 1.6 days from school because of colds, and those who received vitamin C in only a small dose, 200 mg per day, lost only an average of 1.1 days, 31 percent less. The probability that this difference would occur in a uniform population is only 0.1 percent, so that it is highly likely that this decrease in the amount of illness was caused by the ascorbic acid. In such a test, the best experiments are those in which the subjects are divided into two groups, in a random way, with the substance being tested (ascorbic acid) administered to the subjects in one group, and a placebo (an inactive material resembling the preparation to be tested: for example, a capsule containing citric acid might be used as a placebo for ascorbic acid) administered to those of the other group. In a blind experiment the subjects do not know whether or not they are receiving the placebo. Sometimes a double-blind study is made, in which the investigators evaluating the effects of the preparation and the placebo do not know which of the subjects received the preparation and which received the placebo until the study is completed, this information being kept by some other person. The results of the first carefully controlled, double-blind study with a larger daily amount, 1000 mg, of ascorbic acid were reported in 1961 by Dr. G. Ritzel, a physician with the medical service of the school district of the city of Basel, Switzerland. He carried out the study at a ski resort with 279 boys during two periods of five to seven days. The conditions were such that the incidence of colds during these short periods was large enough (approximately 20 percent) to permit results with statistical significance to be obtained. The subjects were of the same age (fifteen to seventeen) and had similar nutrition during the period of study. In accordance with the double-blind protocol, neither the participants nor the physicians had any knowledge about the distribution of the 1000-mg ascorbic-acid tablets and the placebo tablets. The tablets were distributed every morning and were taken by the subjects under observation in such a way that the possibility of interchange of tablets was eliminated. The subjects were examined daily for symptoms of colds and other infections. The records were largely on the basis of subjective symptoms, partially supported by objective observations (measurement of body temperature, inspection of the respiratory organs, auscultation of the lungs, and so on). Persons who showed cold symptoms on the first day were excluded from the investigation. After the completion of the investigation a completely independent group of professional people carried out the statistical evaluation of the observa tions with the identity of the recipients of the ascorbic acid and the placebo
tablets concealed by identification numbers. The group receiving ascorbic acid showed only 39 percent as many days of illness per person as the group receiving the placebo; the number of individual symptoms per person was only 36 percent as great for the ascorbic-acid group as for the placebo group. The statistical evaluation showed that these differences are statisti cally significant at better than the 99 percent level of confidence. We see that in RitzePs study the vitamin-C subjects had only about one-third as much illness as the placebo subjects. In another ski-camp study, with forty-six students as subjects, BesselLorck (1959) found that those students who received 1 g of vitamin C per day had only about half as much illness as those who received no vitamin C. After the publication of my Vitamin C and the Common Cold, several excellent double-blind studies were carried out. The first one, in Toronto, Canada (Anderson, Reid, and Beaton, 1972) involved 407 subjects receiv ing ascorbic acid (1 g per day plus 3 g per day for three days at the onset of any illness) and 411 subjects receiving a closely matching placebo. The duration of the study was four months. The number of days confined to house per subject was 30 percent less for the ascorbic-acid group than for the placebo group, and the number of days off work per subject was 33 percent less. The authors mention that these differences have high statisti cal significance (99.9 percent level of confidence). Another study, under quite different conditions, involved 112 sol diers undergoing operational training in northern Canada (Sabiston and Radomski, 1974). Half of the subjects received 1 g of ascorbic acid per day during the four weeks of the study, and the other half received a placebo. The average number of days of illness was 68 percent less for the ascorbicacid subjects than for the placebo subjects. The average amount of protection against the common cold found in these four studies in which 1 g or 2 g was given per day is 48 percent; that is, on the average, the subjects who received vitamin C had only about onehalf as much illness as those who received the inactive tablet. Since identical twins have, in principle, identical immune systems, they commend themselves for studies of this kind. Two unfortunately flawed studies comparing one twin on placebo and the other on vitamin G have been reported. Carr and his colleagues conducted a hundred-day double blind study of ninety-five pairs of identical twins in Australia, fourteen to sixty-four years old, average twenty-five years, in which one of each pair took a 1000-mg tablet of vitamin C each day and the other took a wellmatched placebo, with all subjects also taking a vitamin tablet containing 70 mg of vitamin G. The results of this study were published in three separate articles (Carr, Einstein, et al., 1981a, 1981b; Martin, Carr, et al.,
1982.) Of the ninety-five pairs of twins, however, fifty-one pairs were living together. For these pairs there was little difference in the amount of illness between the twin with the high intake of C and the twin with the low intake. I think that the probable explanation is that the twins living together were not careful about taking their own tablets. Moreover, close exposure to the other’s cold might well override whatever protection was afforded to the twin taking vitamin C. For the forty-four pairs of twins living apart the average number of days of illness was 6.32 for the highintake twins and 12.08 for the low-intake twins, corresponding to 48 per cent protection by the extra 1000 mg of vitamin C per day. In the other twin study, by Miller et al. (1977, 1978) forty-four pairs of identical twins were given 500, 750, and 1000 mg of vitamin C per day, depending on age, or a starch placebo. There was little difference in the amounts of illness of the vitamin-C twins and the placebo twins. All of these pairs of twins lived at home, and the same effects of mixing their tablets and exchanging their infections may have occurred. Many other physicians have reported their observations that vitamin G seems to have value in helping to control the common cold, as well as other diseases. From a study of 2600 factory workers in Leipzig, Scheunert (1949) reported that an intake of either 100 mg or 300 mg of vitamin C per day decreased the incidence of respiratory diseases and other diseases by about 75 percent. Bartley, Krebs, and O’Brien (1953) found that the mean length of colds in subjects deprived of ascorbic acid was twice as great as for subjects not deprived. Fletcher and Fletcher (1951) stated that supplements of 50 mg to 100 mg of ascorbic acid per day increased the resistance of children to infection. Some value of small amounts of ascorbic acid was reported also by Barnes (1961), Macon (1956), and Banks (1965, 1968). Marckwell (1947) stated that there was a 50 percent chance of stopping a cold if enough ascorbic acid was taken: 0.75 g at once, followed by 0.5 g every three or four hours, continuing on later days if needed. In the July-August 1967 issue of the magazine Fact there appeared an article entitled “Why Organized Medicine Sneezes at the Common Cold” by Dr. Douglas Gildersleeve, apparently a pseudonym for a physician who feared the consequences of writing heresy in a popular magazine. The author reported that he could suppress the symptoms of the common cold by making use of twenty or twenty-five times as much ascorbic acid as the 200 mg per day used by investigators whose reports he had read. In studies carried out on more than four hundred colds in twenty-five individuals, mostly his own patients, he had found the treatment with ascorbic acid in large amounts to be effective in 95 percent of the patients. The most fre quent cold symptom, excessive nasal discharge, disappeared entirely on use of ascorbic acid, and other symptoms—sneezing, coughing, sore throat,
hoarseness, and headache—were barely noticeable, if they were present at all. He reported that not one of the subjects ever experienced any secondary bacterial complications. In this article Gildersleeve reported that in 1964 he wrote a paper in which he described his observations. He submitted the paper to eleven different professional journals, every one of which rejected it. One editor said to him that it would be harmful to the journal to publish a useful treatment for the common cold. He stated that medical journals depend for their existence on the support of their advertisers, and that more than twenty-five percent of the advertisements in the journals relate to patented drugs for the alleviation of cold symptoms or for the treatment of complica tions of colds. Another editor said that he had rejected the paper because it was not correct. When Gildersleeve questioned him about this statement, he said, “Twenty-five years ago I was a member of a team of researchers that investigated vitamin G. We determined then that the drug was of no use in treating the common cold.” He was not impressed when Gildersleeve told him that the amount of ascorbic acid that had been used in the early work was only one-twentieth of the minimum amount necessary to achieve sig nificant results. Explaining “Why Organized Medicine Sneezes at the Common Cold,” Gildersleeve concluded: “. . . having worked as a researcher in the field, it is my contention that an effective treatment for the common cold, a cure, is available, that [it] is being ignored because of the monetary losses that would be inflicted on pharmaceutical manufacturers, professional journals, and doctors themselves.” • Some other studies have addressed the therapeutic value of vitamin C in treating, as distinguished from preventing, the common cold. They confirm the experience reported by the pseudonymous Dr. Gildersleeve. In 1938 Ruskin reported his observations on more than one thousand patients to whom he had given an injection, sometimes followed by a second one, of 450 mg of calcium ascorbate as soon as possible after the onset of a cold. He found that 42 percent of the patients were completely relieved and another 48 percent were markedly improved. He concluded that “calcium ascorbate would appear to be practically an abortive in the treatment of the common cold.” Several other somewhat similar reports are mentioned by Irwin Stone in his book The Healing Factor: Vitamin C against Disease (1972). Stone himself recommended taking 1.5 to 2 g of ascorbic acid by mouth at the first sign of a cold, with the dose repeated at twenty-minute to half hour intervals until the symptoms have disappeared, which occurs usually by the third dose. The physician Edme Regnier of Salem, Massachusetts, reported in 1968 that he had discovered the value of the administration of large doses of
ascorbic acid in the prevention and treatment of the common cold. For many years, beginning at the age of seven, he had suffered from repeated bouts of inflammation of the middle ear. He had tried a number of ways of controlling the infections, and after twenty years he tried the bioflavonoids (from citrus fruits) and ascorbic acid. He felt that this treatment had been of some benefit but not very great. He decided to try increasing the amount. After several trials he found that the serious and disagreeable manifesta tions of the common cold and the accompanying inflammation of the middle ear could be averted by the use of large amounts of ascorbic acid and that ascorbic acid alone was just as effective as the same amount of ascorbic acid plus bioflavonoids. He then initiated a study of twenty-one subjects with use of ascorbic acid alone, ascorbic acid plus bioflavonoids, bioflavonoids alone, or a placebo. This study extended over a period of five years. At first the subjects were kept ignorant of the preparations that they received, but later on (during the last year) it became impossible to continue the blind study, because a patient whose cold was developing recognized that he was not receiving the vitamin C that might have prevented it. The method of treatment recommended by Regnier is the administration of 600 mg of ascorbic acid at the first signs of a cold (scratchiness of the throat, nasal secretion, sneezing, a chill), followed by an additional 600 mg every three hours or 200 mg of ascorbic acid every hour. At bedtime the amount ingested is increased to 750 mg. This intake, amounting to about 4 g of ascorbic acid per day, is to be continued for three or four days, reduced to 400 mg every three hours for several days, and then to 200 mg every three hours. Regnier reported that of thirty-four colds treated with ascorbic acid plus bioflavonoids, thirty-one were averted, and of fifty colds treated with ascorbic acid alone, as described above, forty-five were averted. He had no success in treating colds with bioflavonoids alone, or with a placebo. He made the important observation that a cold that has been apparently aborted by the use of a large intake of ascorbic acid may return, even after a period of a week or more, if the ingestion of ascorbic acid is suddenly dis continued. Even nearly 3 g per day for three days (2.66 g the first and second days; 1.33 g the third day) may not be effective if the treatment is delayed until after the cold has begun, as reported by Cowan and Diehl (1950). A similar lack of effectiveness of 3 g per day, starting after the cold had developed, was also reported by a group of seventy-eight British physicians (Abbott et al., 1968). In a study carried out by the British Common Cold Research Unit in Great Britain (Tyrrell et al., 1977) with 1524 volunteers employed in industrial plants in several parts of England, each subject was given a vial containing ten effervescent tablets. Some of the vials contained 1000 mg of
vitamin C per tablet, and others contained a placebo. The instructions were to take the tablets for 2.5 days, beginning when the first symptoms of a cold developed. The fraction developing a first cold was nearly the same, 31.1 percent for the vitamin-G group and 33.2 percent for the placebo group. No difference would be expected, since the two groups were on the same regi men until the first cold developed. There was no difference in the duration of the colds. The lack of effect of taking 10 g of vitamin C during the first 2.5 days indicates that high doses of vitamin C should be taken until the cold is controlled. This finding corroborates Regnier’s opinion on the likely return of aborted colds. If the cold is not completely suppressed, the rebound effect from the stopping of vitamin G intake may help in permitting it to run its full course. One significant observation was made in the study by the Common Cold Research Unit. Of the 101 male vitamin-C subjects who experienced a first cold during the four months of the trial, 23 developed a second cold later on, whereas of the 98 similar male placebo subjects, nearly twice as many, 43, developed the second cold. This twofold difference has high statistical significance. The 10 g of vitamin C taken for the first cold may have had a strengthening effect on the immune system lasting a month or two. The difference in incidence of the second cold was not observed for the women in the study, possibly because vitamin-C depletion is not so serious for British women as for the men. In a second Toronto study (Anderson et al., 1974), in which there were 2349 volunteers divided into eight groups, one group of 275 took 4 g of vitamin C on the first day of a cold and the second took 8 g on the first day, with no regular intake for either group. There was no clear benefit for the first group, but the authors point out that the 8-g therapeutic dose was associated with less illness than the 4-g therapeutic dose. The protective effect, measured by the decrease in number of days when individual symp toms were recorded, was about 5 percent for the single 4-g dose and 20 percent for the single 8-g dose. The best study of the therapeutic effect of vitamin C was carried out by Asfora (1977), who gave 30 g of vitamin C or a placebo to 133 subjects (medical students, physicians, or clinic patients in Pernambuco) who had reported a developing cold. The vitamin C was given as effervescent 1000 mg tablets, with instructions that six should be taken each day (two at a time, three times a day) for five days; the placebo consisted of similar effervescent tablets. Some patients began on the first day of the cold, others on the second, and others on the third, as shown in the table on page 119. The number of subjects for whom the treatment may be said to have failed completely, in that they developed secondary bacterial infections and were ill for an average of 15 days, was 13 percent for the first-day vitamin-
Results of a controlled trial of the therapeutic value of 30 g of vitamin C (6 g per day for 5 days) beginning on the first, second, or third day of a cold. Group
I
11
III
IV
Number of subjects: male/female Day of beginning vitamin C Fraction with bacterial complications Average days of illness: with complications without complications
45 25/20 1
30 17/43 2
17 11/6 3
41 25/16 placebo
13% 3.6 15.2 1.82
20% 5.4 16.0 2.71
41% 9.0 14.6 5.10
39% >5* >5a >5a
aNot recorded
C subjects, 20 percent for the second-day subjects, and 41 percent for the third-day subjects (also 39 percent for the placebo group). For the remain ing subjects in each group, whose colds were without complications, the average number of days of illness was 1.82, 2.71, and 5.10 for the first-, second-, and third-day subjects. We see that 6 g of vitamin C per day, starting on the first or second day of the cold, stopped it for most of the subjects in this investigation. We have now reviewed about thirty reported studies of the value of vitamin C taken in daily doses in preventing a cold from starting to develop or in reducing the severity of a cold. Some of the investigators have reported that both the incidence and the severity of the colds are decreased by the vitamin C. Thus Ritzel in his study of schoolboys who received 1 g of vitamin C per day reported a decrease in incidence (number of colds per subject) by 15 percent and also a decrease by 19 percent in the severity of individual colds (the number of days of illness per cold). Others have re ported only a small decrease in incidence. Anderson has pointed out that with a small number of symptoms observable early in a cold, it is hard to decide whether the subject has a cold or not. In the table on page 120 I have listed the results of sixteen trials, com prising all of the trials known to me that meet certain specifications. One is that ascorbic acid be given regularly over a period of time to subjects who were not ill at the start of the trial, with the subjects selected at random from a larger population. The study by Masek et al. (1972) is not included because the vitamin-C subjects were the workers in one mine and the placebo subjects were those in another, where the conditions affecting the health of the workers might have been either better or worse. In all but one of the studies a placebo, a tablet or capsule closely resembling the vitamin-
C tablet or capsule, was given to the control subjects. The one exception was the carefully conducted and thorough study by Glazebrook and Thom son (1942), in which ascorbic acid was added to the food (cocoa or milk) of one or more of the seven divisions of boys that were served in seven differ ent places in the dining hall. The amount of illness per subject found in these sixteen controlled trials varies from 1 percent to 68 percent, and there is no clear indication that an intake of 1000 or 2000 mg per day gives greater protection than 70 to 200 mg per day. The studies giving the smallest and largest protective effects had soldiers as subjects. In the Pitt and Costrini study the marine recruits were in barracks in South Carolina. There was no protective effect against colds, but there was a significant protective effect against pneumonia. The Sabiston and Radomski study was carried out under more severe condi tions, with soldiers living in tents in northern Canada, and the number of Summary of results of controlled studies of amount of illness per subject in vitamin C subjects relative to placebo subjects. Study
Amount of decrease in illness per person, percent
aGlazebrook & Thomson (1942) aCowan, Diehl, Baker (1942) aDahlberg, Engel, Rydin (1944) aFranz, Sands, Heyl (1954) aAnderson et al. (1975) Ritzel (1961) Anderson, Reid, Beaton (1972) Charleston, Clegg (1972) Elliott (1973) Anderson, Suranyi, Beaton (1974) Coulehan et al. (1974) Sabiston & Radomski (1974) Karlowski et al. (1975) Clegg & Macdonald (1975) Pitt & Costrini (1979) Carr et al. (1981) Average
50 31 14 36 25 63 32 58 44 9 30 68 21 8 0 48 34
*70 to 200 mg per day, average 31%; others, larger intakes, average 40%.
colds per subject was three times as great as for the South Carolina study. A possible explanation is that the amount of vitamin C in the rations of the marine recruits in South Carolina was much greater than that in the ra tions of the Canadian soldiers, providing greater protection for the marine recruits. It may be pertinent that in the 1975 study of Canadian subjects by Anderson, Beaton, Corey, and Spero there was a 25 percent protection, even though the intake of supplementary vitamin C was only one 500-mg tablet per week, equal to 70 mg per day. The average intake of vitamin C in the food in Canada is known to be less than that in the United States. A principal reason for the failure of most of the controlled trials to show a large prophylactic or therapeutic effect is that the amounts of vitamin C taken are too small. It is as if the physicians and nutritionists reasoned, fallaciously, that since a tiny dose of vitamin C will cure scurvy, why should it take an astronomical dose to cure the common cold. Even so, the average of the sixteen values of the decrease in the amount of illness per person is 34 percent. For the five studies in which only 70 mg to 200 mg of ascorbic acid per day was given the average is 31 percent, and for the eleven in which 1 g per day or more was given it is 40 percent. We may conclude that even a small added intake of vitamin C, 100 mg or 200 mg per day, has considerable value, and that a larger intake probably has somewhat more value.* The studies I have reviewed here fall short of the standards I have in mind not only because too little vitamin C was administered but also be cause the vitamin was not taken over a long enough period of time and biochemical individuality—different needs for different persons—was not considered. The factor of biochemical individuality is clearly shown in the illustration entitled “Vitamin C and schizophrenia” in Chapter 10. The fraction of a standard amount, 1.76 g, of vitamin C taken by mouth that is excreted in the urine during the next six hours varies from about 3 percent to about 30 percent. People representing these extremes might well respond differently to vitamin C taken to control the common cold. Dr. Robert F. Cathcart, about whose work I shall have more to say in the next chapter, has had extensive experience in administering vitamin C
*In addition to the studies cited in this chapter, a number of others are discussed in my 1976 book Vitamin C, the Common Cold, an d the Flu. Some of these are the following: Anderson, Reid, and Beaton, 1972; Anderson, Suranye, and Beaton, 1974; Anderson, Beaton, Corey, and Spero, 1975; Charleston and Clegg, 1972; Masek, Neradilova, and Hejda, 1972; Elliott, 1973; Coulehan et al., 1974; Wilson, Loh, and Foster, 1973; Karlowski et al., 1975; Franz, Sands, and Heyl, 1956; Clegg and Macdonald, 1975; Carr et al., 1981, 1982; Miller et al., 1977, 1978. The results are summarized in the following chapter.
to patients with colds. His observations on many thousands of patients have led him to conclude that the doses of vitamin C needed to control a viral disease depend on the nature of the disease and on the nature of the patient. In his 1981 report he suggests that you cannot cure a “100-gram cold” by taking a few grams of vitamin C. The proper intake of vitamin C needed to control a viral infection, Cathcart found, is an intake just below the amount that causes a loose, watery bowel movement—increase in the intake of vitamin G to a suffi ciently large amount does have a laxative effect, at first. This bowel-toler ance intake is said by him to be between 4 and 15 g per twenty-four hours for people in “ordinary good health,” and to have much larger values for the same persons, up to more than 200 g per twenty-four hours, when they are suffering from a viral disease. A similar observation with cancer pa tients was also made by Dr. Ewan Cameron. We can now see how difficult it would be to carry out a proper trial of vitamin C and the common cold. The dose should be determined for each subject by the bowel-tolerance limit. It might be possible to formulate a suitable placebo with a bowel-tolerance limit, but it is clear that it would not be easy to carry out a controlled trial with the high intakes that are needed for 100 percent effectiveness. I have received hundreds of letters from people who say that they have for years had freedom from colds after they began taking 500 mg, 1 g, 3 g, 6 g, or more vitamin G per day. We know that the 6 to 10 percent of people who never have colds must have enough vitamin C in their food. It is not unreasonable to believe that another 6 to 10 percent are close enough to this resistance that a supplement of 500 mg per day would protect them; an other group might require 1000 mg per day, and others still more. I believe that every person can protect himself or herself from the com mon cold. Catching a cold and letting it run its course is a sign that you are not taking enough vitamin C. I am convinced by the evidence now available that vitamin C is to be preferred to the analgesics, antihistamines, and other dangerous drugs that are recommended for the treatment of the common cold by the purveyors of cold medicines. Every day, even every hour, radio and television commer cials extol various cold remedies. I hope that, as the results of further stud ies become available, extensive educational efforts about vitamin C and the common cold will be instituted on radio and television, including warnings against the use of dangerous drugs, like those about the hazards of smoking that are now sponsored by the United States Public Health Service, the American Cancer Society, the Heart Association, and other agencies.
14.I n f l u e n z a I n f e c tio u s
a n d
O
t h e r
D is e a s e s
Though people often diagnose themselves as having “the flu,” influenza is not the same disease as the common cold. Some of the signs and symptoms, such as increased nasal secretion, are similar, but influenza is a highly contagious, potentially life-threatening disease. Like the common cold, it is caused by a virus. The influenza viruses belong, however, to a different family from the cold viruses, and the two diseases manifest themselves in some significantly different ways. The incubation time for influenza (time from exposure to onset of symp toms) is short, about two days. The onset usually is sudden. It is marked by chills, fever, headache, lassitude and general malaise, loss of appetite, mus cular aches and pains, and sometimes nausea, occasionally with vomiting. Respiratory symptoms, such as sneezing and nasal discharge, may be pres ent but are usually less pronounced than with the common cold. Coughing, without production of sputum, may occur, and hoarseness sometimes devel ops. The fever usually lasts for two to four days. In mild cases the tempera ture reaches 101 °F to 103°F (38.3°C to 39.4°C) and in severe cases as much as 105°F (40.6°C). Treatment consists of rest in bed, continuing for twenty-four to fortyeight hours after the temperature has become normal. Antibiotics may be used to control bacterial infections. The diet should be light, with a large
intake (3000 to 3500 milliliters (ml) per day, about 7 pints) of water and fruit juices. Except during a pandemic, when an especially virulent strain infects most of the population in a country or several countries, almost all of the patients recover completely. Influenza is an old disease. Hippocrates in his book Epidemics described a disease raging at Perinthos in Crete about 400 B.C. in such a way as to permit its identification as influenza. An influenza epidemic was reported in 1557-1558, and a pandemic spread throughout Europe in 1580-1581. Other epidemics or pandemics broke out in 1658, 1676, 1732-1733, 1837, 1889-1890, 1918-1919, 1933, and 1957, and a mild one in 1977-1978. The most serious influenza pandemic was that of 1918-1919. It swept over the whole world in three successive waves, May to July 1918, Septem ber to December 1918, and March to May 1919. It is thought to have arisen in Spain, and it was popularly called the Spanish flu (Collier, 1974). It broke out almost simultaneously in all the European nations and prob ably was rapidly spread because of the movements of troops and because of wartime conditions. The first wave did not reach some parts of the world, including South America, Australia, and many islands in the Atlantic and Pacific Oceans. The second wave, which caused most of the deaths, covered the whole world except the islands of St. Helena and Mauritius. Between 80 and 90 percent of the people in most countries contracted the disease, and about twenty million died. The disease was clearly not the same as ordinary influenza, because in 1918-1919 most of the deaths occurred among young people, whereas in the preceding and following years most of the deaths from influenza were among the old. From 1892 to 1918 it was thought that influenza was caused by a bacte rium, called Pfeiffer’s bacillus, that had been isolated from sputum or blood of influenza patients. Then in 1918 the French investigator Debre observed a similarity in the immune response of patients with influenza to those with measles, a viral disease, and concluded that influenza was probably also caused by a virus. Proof of this suggestion was immediately reported by Selter (1918) in Germany, Nicolle and Lebailly (1918) in Tunis, and Dujarric de la Riviere (1918) in France. The proof was obtained by forcing infected sputum and blood through a filter with pores so fine that no bacte ria could pass through them. It was found that the filtered liquid put in the nasal passage of monkeys and of human volunteers caused them to develop the disease, which was accordingly ascribed to a “filterable” virus, the par ticles of which are much smaller than bacteria. Isolation of strains of influenza virus, permitting thorough studies of their properties to be made, was achieved in 1933 by the British investiga tors Wilson Smith, Christopher Andrewes, and Patrick Laidlaw. An ac count of their procedure was published by Andrewes in 1965. During the
influenza epidemic of 1933 Andrewes and Smith, both of the British Na tional Institute for Medical Research, were working on influenza when Andrewes became ill with the disease. Smith had him gargle with salt water and used the solution in an attempt to infect rabbits, guinea pigs, mice, hedgehogs, hamsters, and monkeys, but without success. Laidlaw, in the same institute, had been able to infect ferrets with dog distemper; he found that the Andrewes’s gargiings introduced into the noses of ferrets caused them to become ill with the flu. Later a way was found to infect mice with influenza. In fact, there had for a long time been evidence that some strains of influenza virus infect certain animals, as well as human beings. Observers had noted that in the 1732 epidemic horses seemed to be suffering from the same disease as people. The virus that caused the 1918-1919 pandemic has been shown to be antigenically identical with porcine influenza virus (swine-flu virus). The virus was not studied during the pandemic itself; the methods for doing so were not developed until fifteen years later. In 1935, however, Andrewes showed that persons twenty years old or older had a high concentration of antibodies against swine-flu virus in their blood, whereas children younger than twelve had none. The clear conclusion is that swine-flu virus was infecting children at some time between 1915 and 1923, presumably 1918-1919. Thorough studies have led to the classification of influenza viruses into several types, each with many strains. The types are A (with subtypes AO, Al, and A2), B, and C. All nonhuman-flu viruses are of type A. A person who has recovered from an infection with one type of the virus is immune to it for some time but not to the others. Some protection against influenza is provided by the injection of a vac cine. The vaccine is prepared by growing the virus on embryonated (fertile) eggs, removing the allantoic fluid, which contains the crop of virus parti cles, and inactivating them by treatment with formaldehyde. The inacti vated virus is no longer infective; that is, it is no longer able to stimulate the cells of a human being or other host to produce additional virus particles. It is, however, able to act as an antigen, causing the host to produce molecules of its specific antibody. This antibody can combine with active virus parti cles and neutralize them, thus protecting the immunized person against the disease. Vaccines are usually made with strains of viruses that are prevalent in the country at the time. Immunity from the vaccination lasts for about one year, after which booster doses extending the protection for another year may be given. The protection provided by vaccination is estimated to be 70 to 80 percent. Its failure may usually be ascribed to infection by a strain of virus differing from the strains used in making the vaccine; new strains
seem to be continually arising. The partial protection provided by vaccina tion is considered to be especially important for old people and people with chronic diseases. There are some possible side effects of the vaccination. Persons with a history of sensitivity to eggs should not be given the vaccine. Some persons suffer from local or systemic reactions to the vaccine, but immediate reac tions followed by death are very rare. Because of the possible side effects, physicians usually advise their patients to be vaccinated only when there is a special reason. The imminence of an epidemic may constitute such a reason, especially for persons who, because of age or illness, are deficient in their natural protective mechanisms and for persons who are occupation ally exposed, such as those in hospitals and clinics. The importance of influenza is made clear by a 1973 report by Schmeck, based on unpublished data from the National Center for Health Statistics. In the ranking of diseases according to their impact on health in 1971, influenza and pneumonia (which often is a sequel in influenza) came first in days of disability in bed in 1971 (206,241,000), with upper respiratory infections second (164,840,000) and heart disease third (93,137,000). In deaths, influenza and pneumonia rank fourth (56,000), behind heart dis ease (741,000), cancer (333,000), and cerebrovascular disease (208,000). The best protection against the flu is one’s natural defense mechanisms. These defense mechanisms seem to have protected about one-sixth of the people during the 1918-1919 pandemic, presumably for the most part those people whose defense mechanisms were operating most effectively. There is much evidence, discussed in connection with the common cold, that a good intake of vitamin C improves the functioning of the natural defense mechanisms to such an extent that a much larger fraction of the population would resist the infection. The proper use of vitamin C, to gether with vaccination when its use is indicated, should be effective in preventing an influenza pandemic or serious epidemic. In 1976 there was fear that another swine-flu epidemic like the one in 1918-1919 would occur. The United States federal government appropri ated $165 million to subsidize the preparation of vaccines, and many mil lion people were vaccinated. The serious epidemic did not occur. A suffi cient number of the vaccinated persons suffered serious side effects from the vaccine to compel termination of the program. The worst of these side effects was the Guillain-Barre syndrome, a neuritis characterized by mus cular weakness and sensory disturbances of the extremities. The measures to be taken for the prevention and treatment of influenza through use of vitamin C are essentially the same as for the common cold. For most people the regular intake of 1 gram (g) or more per hour should be begun. Also, a high intake of vitamin C should not be used as an excuse
for continuing to work until exhaustion sets in. A person who may be contracting a cold or influenza should go to bed, rest for a few days, and take plenty of fluids along with vitamin C, to have a much greater chance of avoiding serious illness. If you have a fever for more than a couple of days, or a very high fever, be sure to call your physician. A good intake of vitamin C should prevent a secondary bacterial infec tion from beginning. If it does begin, your physician can control it by a suitable regimen with antibiotics. Some physicians might inject large amounts of sodium ascorbate. Persons at special risk, such as those with heart, lung, kidney, and cer tain metabolic diseases, including diabetes, may be advised to be vaccinated against influenza, as may also doctors, nurses, and others exposed to the virus to more than the usual extent. They should also take vitamin C; it will protect against the side effects of the vaccination, as well as against the disease. If an attack of influenza begins and is not stopped by vitamin C, you should continue to take the vitamin in large amounts. It should make the attack a light one, of short duration. Vitamin C has value in preventing and treating not only the common cold and influenza but also other viral diseases and various bacterial infec tions. Its main mechanism of action is through strengthening the immune system, as was discussed in Chapter 12. It may also have a direct antiviral effect, in some way inactivating the virus. There are very few drugs that are effective against viral infections, so that the value of the indicated antiviral action of vitamin C is especially great. Most bacterial infections can be treated successfully with the appropriate antibiotics or other drugs, but vitamin C also has value as an adjunct to this treatment. In 1935 Dr. Claus W. Jungeblut, working in the College of Physicians and Surgeons of Columbia University, was the first person to report that vitamin C, in concentrations that can be reached in the human body by a high intake, inactivates poliomyelitis virus and destroys its power of causing paralysis. He and other investigators showed that the vitamin inac tivates herpes virus, vaccinia virus, hepatitis virus, and others (references to the early work are given by Stone, 1972). Jungeblut, who died in 1976, lived long enough to see greatly increased interest and activity in the field in which he pioneered. The antiviral effect of vitamin C has also been studied by Murata and coworkers. Using viruses that infect bacteria as their model, they showed that these viruses are neutralized by a free-radical mechanism. Dr. Fred R. Klenner, a physician in Reidsville, North Carolina, was stimulated by Jungeblut’s report to use vitamin C in the treatment of patients with poliomyelitis, hepatitis, viral pneumonia, and other diseases
(Klenner, 1948 to 1974). His suggested dose, by intravenous infusion, for viral hepatitis is 400 to 600 mg per kilogram body weight; that is, 28 to 42 g for a 150-pound person, repeated every eight to twelve hours, and he has administered up to twice this amount for various viral diseases (Klenner, 1971, 1974). In addition to the antiviral action of vitamin C, many investigators have reported that ascorbate inactivates bacteria. One of the earliest studies was that of Boissevin and Spillane (1937), who showed that an ascorbate con centration of 1 milligram (mg) per deciliter, which is easily reached in the blood, prevents the growth of cultures of the tuberculosis bacterium. Effec tiveness of ascorbate in inactivating many other bacteria and their toxins has also been reported, including the toxins of diphtheria, tetanus, staphy lococcus, and dysentery and the bacteria that cause typhoid fever, tetanus, and staphylococcus infections (references are given by Stone, 1972). The mechanism of the inactivation seems to be similar to that for viruses: attack by free radicals formed by ascorbate and molecular oxygen, catalyzed by copper ions (Ericsson and Lundbeck, 1955; Miller, 1969). Klenner (1971), McCormick (1952), and others have reported a consid erable degree of success in treating various bacterial infections in humans with large doses of vitamin C. This success may be attributed to some extent to the direct inactivation of the bacteria, for which evidence is pre sented in Chapter 13, but I think that for the most part it results from the action of the vitamin in increasing the power of the natural protective mechanisms of the body (Cameron and Pauling, 1973, 1974). Hepatitis is inflammation of the liver caused by infections or toxic agents. It usually causes jaundice, a yellowness of the skin and the whites of the eyes resulting from an excess of bile pigments in the blood. Toxic substances such as carbon tetrachloride and various drugs, as well as heavy metals, may cause toxic hepatitis. Vitamin C is of some value in preventing toxic hepatitis because it has rather general detoxifying capability by hydroxylating or glycosylating toxic organic compounds and by combining with heavy metals. Infectious hepatitis may be caused by viruses or bacteria, usually by viruses introduced by fecally contaminated food or water. The usual treat ment is bed rest for three weeks or more. Serum hepatitis (hepatitis B, inoculation hepatitis) is caused by a different virus, hepatitis-B virus, and is usually transmitted to the patient by blood transfusions or use of unsterile hypodermic needles or dentists’ drills. The incubation time is one to five months. Serum hepatitis occurs mostly in older people. It is more serious than infectious hepatitis, with mortality as high as 20 percent in some studies. Dr. Fukumi Morishige in Japan became interested in vitamin C while he was a medical student: his thesis was on the value of the vitamin in
accelerating the healing of wounds. When he became a thoracic surgeon and the head of a hospital in Fukuoka, Japan, he gave moderately large doses of vitamin C to some surgical patients who had received blood trans fusions. He noticed that these patients did not develop serum hepatitis, whereas similar patients who did not receive the supplementary vitamin had a 7 percent incidence of the infection. In 1978 he and Murata reported their observations on 1537 Surgical patients who had received blood trans fusions in Torikai Hospital in Fukuoka between 1967 and 1976. Of the 170 patients who received little or no vitamin G, 11 developed hepatitis, an incidence of 7 percent, whereas of the 1367 patients who received from 2 to 6 g of vitamin G per day only 3 cases (all non-B) occurred, an incidence of only 0.2 percent. These numbers indicate that 93 patients were saved from the suffering and danger of hepatitis by the vitamin G (Morishige and Murata, 1978). A high intake of vitamin G protects the liver in several ways. It detoxifies poisonous substances that might cause toxic hepatitis. By this effect, it also helps to prevent damage to the liver from cigarette smoking and over indulgence in alcoholic drinks. By making the immune system more effec tive, it helps to prevent and control viral and bacterial infections of the liver. The physician who has had the greatest amount of experience with vita min G and viral diseases is Dr. Robert Fulton Gathcart III, of San Mateo, California. Gathcart was for several years an orthopedic surgeon. In his practice he implanted in many patients a hip-joint prosthesis, a metal ball attached to a spike that fits inside the upper end of the femur and replaces the round part of this upper leg bone. This prosthesis had been developed by Austin Moore, an English investigator. Gathcart was troubled by the failure of the implant in many of the patients because of erosion of the hip socket into which the ball fits. He decided to find out why the prosthesis was not more successful. He examined many human hip bones and noticed that the ball at the top of the femur is not spherical but spheroidal, and he designed a new prosthesis conforming more closely to the shape of the femur. Many thousands of the Gathcart prostheses have now been implanted. In 1971, shortly after my book Vitamin C and the Common Cold was published, Cathcart wrote me to tell how he had read the book and by following its recommendations had succeeded in controlling the serious res piratory infections and infections of the inner ear that had plagued him since childhood. He reported that a single dose of 8 g of vitamin G taken at the first sign of a cold usually stopped it, although often additional doses were needed. He was so much impressed by the effectiveness of vitamin G that he gave up his practice as an orthopedic surgeon and became a general practitioner, specializing in the treatment of infectious diseases (Pauling, 1978). By 1981
he was able to report on his observations on 9000 patients treated with large doses of vitamin C (Cathcart, 1981). Cathcart makes it his practice to establish for each of his patients their bowel-tolerance intake of vitamin C—the amount of vitamin G taken by mouth that is a little less than the amount that has a troublesome laxative effect. He found that vitamin C is most effective as an adjunct to appropri ate conventional therapy, when needed, if it is ingested at the bowel-toler ance intake. This intake is different for different people and different for the same person at different times. Cathcart observed that the bowel-toler ance intake is usually very large for seriously ill patients and becomes smaller as the patient’s health improves. He was astonished that for some severely ill patients the bowel-tolerance limit was more than 200 g per day. Within a few days, as the disease was controlled, the limit would fall toward the normal values, 4 to 15 g per day. Having thus established a standard for administering vitamin C to his patients in a manner responsive to their biochemical individuality, Cathcart has accumulated a wealth of experience with this orthomolecular treatment of many different kinds of infection. He indicates that vitamin C has little effect on acute symptoms until doses of 80 to 90 percent of bowel tolerance are reached. He also has stated that suppression of symptoms in some instances may not be total but usually is very significant, and often the amelioration is complete and rapid. It is known that many stressful conditions cause destruction of vitamin C and consequently low concentrations of the vitamin in the blood and other tissues, unless it is replaced by a high intake of the vitamin. Among these conditions are infectious diseases, cancer, heart disease, surgery, injury, cig arette smoking, and mental and emotional stress. The low level of vitamin C is called hypoascorbemia by Irwin Stone and induced scurvy or anascorbemia by Cathcart. Unless rectified, it leads to exacerbation of the trouble affecting the person. There is the possibility that the mechanism of the ob served increased morbidity and mortality of men and women following the death of a spouse is the destruction of vitamin C by the stressful situation. This may be explained by extra demand for ascorbic acid in the adrenal glands for manufacture of the stress hormone, adrenalin, as shown in Chapter 8. The possible consequences of induced anascorbemia have been described by Cathcart (1981) in the following words: The following problems should be expected with increased incidence with severe depletion of ascorbate; disorders of the immune system such as secondary infections, rheumatoid arthritis and other collagen diseases, allergic reactions to drugs, foods and other substances,
chronic infections such as herpes, or sequelae of acute infections, and scarlet fever; disorders of the blood coagulation mechanisms such as hemorrhage, heart attacks, strokes, hemorrhoids, and other vascular thromboses; failure to cope properly with stresses due to suppression of the adrenal functions such as phlebitis, other inflammatory disorders, asthma, and other allergies; problems of disordered collagen formation such as impaired ability to heal, excessive scarring, bed sores, varicose veins, hernias, stretch marks, wrinkles, perhaps even wear of cartilage or degeneration of spinal discs; impaired function of the nervous system such as malaise, decreased pain tolerance, tendency to muscle spasms, even psychiatric disorders and senility; and cancer from the suppressed immune system and carcinogens not detoxified; etc. Note that I am not saying that ascorbate depletion is the only cause of these disorders, but I am pointing out that disorders of these systems would certainly predispose to these diseases and that these systems are known to be dependent upon ascorbate for their proper function. Not only is there the theoretical probability that these types of complications associated with infections or stresses could result from ascorbate depletion, but there was a conspicuous decrease in the expected occurrence of complications in the thousands of patients treated with oral tolerance doses or intravenous doses of ascorbate. This impression of marked decrease in these problems is shared by physicians experienced with the use of ascorbate such as Klenner (1949, 1971) and Kalokerinos (1974). Infectious mononucleosis (glandular fever) is an acute infection that af fects mainly young people and is sometimes epidemic in schools and col leges. It is characterized by swelling lymph nodes throughout the body and the appearance of abnormal lymphocytes in the blood. The patients, after an incubation period of five to fifteen days, have vague symptoms of head ache, fatigue, fever, chills, and general malaise. Secondary throat infections and liver damage by clogging with lymphocytes sometimes occur, as well as problems with the spleen, nervous system, heart, and other organs. The disease sometimes runs its course in one to three weeks but often is trouble some for several months. Cathcart has reported success in treating mononucleosis with large oral doses of vitamin C (see table on page 132). Here are his comments: Acute mononucleosis is a good example because there is such an obvious difference between the course of the disease, with and without ascorbate. Also, it is possible to obtain laboratory diagnosis to verify
that it is mononucleosis being treated. Many cases do not require maintenance doses for more than 2 to 3 weeks. The duration of need can be sensed by the patient. I had ski patrol patients back skiing on the slopes in a week. They were instructed to carry their boda bags full of ascorbic acid solution as they skied. The ascorbate kept the disease symptoms almost completely suppressed even if the basic infection had not completely resolved. The lymph nodes and spleen returned to normal rapidly and the profound malaise was relieved in a few days. It is emphasized that tolerance doses must be maintained until the patient senses he is completely well, or the symptoms will recur. During recent years a new disease has been recognized, acquired im mune deficiency syndrome, usually called AIDS. It seems to be a viral Usual bowel-tolerance doses (Cathcart) Condition Normal Mild cold Severe cold Influenza ECHO, coxsackievirus Mononucleosis Viral pneumonia Hay fever, asthma Environmental and food allergy Burn, injury, surgery Anxiety, exercise, and other mild stresses Cancer Ankylosing spondylitis Reiter’s syndrome Acute anterior uveitis Rheumatoid arthritis Bacterial infections Infectious hepatitis Candida infections
Grams per 24 hours
Number of doses per 24 hours
4- 15 30- 60 60-100 100-150 100-150 150-200 + 100-200 + 15- 50 0.5- 50 25-150
4 6-10 8-15 8-20 8-20 12-25 12-25 4- 8 4- 8 6-20
15- 25 15-100 15-100 15- 60 30-100 15-100 30-200 + 30-100 15-200 +
4- 6 4-15 4-15 4-10 4-15 4-15 10-25 6-15 6-25
disease, mainly transmitted by fecal matter during sexual contact but some times by blood transfusions. The patients are mainly promiscuous homo sexual men and women, but there are some others, including a few children and infants. The patients develop secondary infections and a form of can cer, Kaposi’s sarcoma, and the disease often results in death. The success of vitamin C in controlling other viral diseases suggests that it be tried with AIDS. Dr. Ewan Cameron, Dr. Robert F. Cathcart, and I separately during the last three years made this proposal to appropriate medical groups, but with no response. One study has been published. Cathcart (1984) examined ninety AIDS patients who had sought medical care from other physicians and who also took high doses of ascorbate on their own initiative, and he also treated twelve AIDS patients with high doses (50 to 200 g per day) of oral and intravenous ascorbate. From his limited observations he has concluded that vitamin C suppresses the symptoms of the disease and can reduce the inci dence of secondary infections. It is evident that additional work along this line is needed. Chemotaxis of phagocytes is an important part of the immune mecha nism (Chapter 12). Chemokinesis is increased movement of the cells, either directed or random, in response to a chemical stimulus, and chemotaxis is increased movement in the right direction, toward the place where they are needed, such as the focus of an infection. Neutrophils are the leukocytes that are most chemotactically responsive—they arrive first at an inflamma tory focus, followed by other phagocytic white blood cells. There are many different causes of abnormal chemotaxis of phagocytes (Gallin, 1981). Many responsible genetic abnormalities are so serious that staphylococcus and other infections and skin problems appear in the first days of life, and most of these infants do not live very long. In several diseases, including rheumatoid arthritis and cancer, substances are released by the diseased tissues into the blood that interfere with the mobility of phagocytes. Many investigators have reported that an increased intake of vitamin G improves the chemotactive response of phagocytes. One of many examples is Anderson (1981), who reported that 1 g of vitamin C per day gave improved neutrophil mobility in children with chronic granulomatous dis ease. Similar improvement has been reported in patients with asthma and tuberculosis. Patrone and Dallegri (1979) concluded that “Vitamin C rep resents the specific therapy for primary defects of phagocytic function in persons with recurrent infections.” The question of phagocytic function invites a digression here from infec tions to genetic disease. Patients with the recessive genetic disease called
Chediak-Higashi disease suffer frequent and severe pyogenic (pus forming) infections that result from abnormal chemotactic responsiveness of neutrophils and other phagocytic cells. These cells are able to move by means of the contraction of actin-myosin fibrils (similar to those in muscle) located in the front edge of the cell. Good locomotion of the cell is permit ted by its structure, its stabilization by rods, called microtubules, that ex tend from the central region to the periphery. The genetic abnormality in Chediak-Higashi disease involves an abnormality in the protein tubulin that by aggregation forms the microtubules. Ten years ago it was discovered that vitamin C enhances neutrophil chemotaxis (Goetzl et al., 1974). Several investigators have reported that increased intake of vitamin C by Chediak-Higashi patients protects them against infections, although it does not correct the abnormality in the tubulin molecules (Boxer et al., 1976, 1979; Gallin et al., 1979). This clear example of the value of vitamin C in controlling infectious diseases in these patients emphasizes its importance for the immune system. Kartagener’s disease is a recessive genetic disorder with low incidence (one in thirty thousand to forty thousand births) and an astonishing collec tion of manifestations. It is characterized by chronic bronchitis and infec tions of the sinuses and middle ears and a tendency to have chronic head ache. Male patients are sterile and have immobile spermatozoa; many patients show situs inversus, with the heart on the right side and some or all of the other internal organs in the right-left reflected positions. These facts raise the question of how the large-scale chirality of the human body is determined. Why do most people have the heart on the left side? What has gone wrong with the patients with Kartagener’s disease who have situs inversus? In the discussion of right-handed and left-handed amino acids in Chap ter 9 it was pointed out that the proteins in the human body are all built of L-amino acids. One of the principal ways of folding the polypeptide chains (linear sequences of amino-acid residues) in proteins is the alpha helix. The alpha helix is required by the handedness of the L-amino-acid residues to be a right-handed helix, like an ordinary screw. The diameter of an amino acid is only about one hundred-millionth of that of a human being, but a segment of alpha helix may be one hundred times as long, thus carry ing the message of handedness to structures as large as one-millionth of the diameter of the body. Another way of transferring chirality to larger structures was discov ered in 1953, when I pointed out that a globular protein molecule, built of perhaps ten thousand atoms, could have two mutually complementary sticky patches on its surface such as to cause it to combine with similar molecules to produce a large helix in the form of a tube (Pauling, 1953).
Such a structure, in units such as the microtubules, can carry handedness throughout a cell. The spermatozoon normally swims by using its tail as a propellor, with a corkscrew motion. The corkscrew (helix) might be either right-handed or left-handed. Its handedness in a normal spermatozoon is determined by little protuberances, called dynein arms, which stick out from the tail to either the right or the left. These dynein arms are missing from the sperma tozoa of patients with Kartagener’s disease; the tails then do not know which way to twist, the spermatozoa do not swim, and the patients are sterile (Afzelius, 1976). In the same way the cilia in the bronchi are unable to wave back and forth to keep the bronchi clear, and the patients are accordingly especially susceptible to bronchitis and associated infections. The tendency to have chronic headaches may result from a defect of the cilia of the epithelial membrane lining the ventricles of the brain and the canal of the spinal cord. The nature of the structures that determine the chirality of the or gans, placing the heart on the left side, is not known, but it is likely that they resemble the dynein arms of the sperm tails. Their abnormality for Kartagener patients might leave the positioning of the heart and other organs to chance, so that half of them would show situs inversus. These patients have abnormal neutrophil chemotaxis that is related to a microtubule abnormality. There is the possibility that their resistance to bacterial infection might benefit from an increased intake of vitamin C, as do the patients with Chediak-Higashi disease, but this has not yet been demonstrated. I have been astonished, as have other people, that in the last quarter of the twentieth century a single substance would be recognized to be helpful no matter what disease a person is suffering from. The reason that vitamin G is such a substance is that by its involvement in many biochemical reac tions in the human body it makes the body’s natural defenses more power ful, and it is these natural defenses that provide most of our resistance to disease. Our bodies can fight disease effectively only when we have in our organs and body fluids enough vitamin C to enable our natural protective mechanisms to operate effectively. The amount required is, of course, much larger than the amount that has been recommended by the authorities in medicine and nutrition in the past.
15.W
o u n d s
a n d
T h e i r
H
e a li n g
A wound is an injury to the body caused by physical means, with disrup tion of the normal continuity of body structure. Accidents and surgical operations cause wounds. Broken bones are wounds. Wounds cause about 150 million visits to physicians per year in the United States. About 75 million people per year suffer injuries, and about 20 million surgical oper ations are carried out. These numbers show that any factor that can in crease the rate of healing of wounds and decrease the length of stay in hospitals can be very valuable. It was observed long ago that when a sailor developed scurvy, old scars from wounds that had been incurred twenty years earlier would break open. Since the healing of wounds requires the generation and laying down of collagen at the site, it would seem wise to call upon vitamin C in its role in the synthesis of collagen (Chapter 9). Murad and his coworkers, who demonstrated the eightfold increase in collagen production in tissue cultures supplied with vitamin C, concluded their paper with this observation: “The clinical implications of this study are appreciable. The importance of ascor bate in wound healing has been recognized for years. Ascorbate is concen trated in wounded tissues and rapidly utilized during wound healing. Ten sile strength of wounds and incidence of wound dehiscence are related to ascorbate levels. Because humans are dependent on dietary sources for as-
corbate, deficiency is common in the elderly as well as sick and debilitated persons, who most commonly undergo surgical treatment. Such patients may need supplemental ascorbate for optimal wound healing.” This is a fine statement, but I shall criticize the last sentence, which reflects the astonishing and often irrational conservatism of the medical establishment in its attitude toward vitamins. Why say “may need supple mental ascorbate,” and why only “sick persons” (elderly, sick, debilitated persons)? The evidence shows clearly that every person needs supplemen tary ascorbate for optimum wound healing. An experimental wound in a subject who for seven months had been on a diet containing no vitamin G failed to heal and then healed normally when the subject was given 1 gram (g) per day of the vitamin for ten days (Lund and Grandon, 1941). Several investigators have reported that surgical wounds do not heal in patients whose blood plasma concentration of ascor bate is less than 2 milligrams (mg) per liter, corresponding to an intake of less than 20 mg per day (references are given in the reviews by Schwartz, 1970). One patient with bilateral hernia and plasma concentration only 0.9 mg per liter was given 100 mg of ascorbic acid per day after the herniorrha phy on one side; after the second operation he was given 1100 mg per day. The skin and fascia wounds on the first side healed poorly, whereas those on the second side healed well, with breaking strength three to six times that for the first side (Bartlett, Jones, and Ryan, 1942). Bourne in 1946 showed that the scar tissue in guinea pigs was much stronger with a high intake of vitamin C (see illustration on page 138), and Collins et al. in 1967 reported that gingival wounds healed in eight days for guinea pigs with a daily intake of 20 mg of vitamin C, twelve days for those with a daily intake of 2 mg, and seventeen days for those receiving no supplementary vitamin. Ringsdorf and Cheraskin (1983) reported a 40 percent decrease in the time of healing standard gingival wounds in human volunteers who received a supplement of 1 g of vitamin C per day. These authors conclude from their review of the published evidence and from their own work that daily doses of 500 to 3000 mg of vitamin C signifi cantly accelerate healing for persons recovering from surgery, decubital ul cers, and leg ulcers caused by hemolytic anemia. I estimate that the length of stay in the hospital could be decreased by an average of two days by the proper use of supplementary vitamin C, not only through its strengthening of the immune system but also through its acceleration of the process of healing of surgical wounds, broken bones, burns, and other injuries. If we take $500 per day as the average cost of hospitalization, the saving in the cost of health care for the forty million patients with short-term stays in hospitals achieved by the administration of between 1 and 20 g of vitamin C per day would be $20 billion per year,
Ascorbic acid, milligrams per day
Vitamin C and scar tissue A 1946 study showed that scar tissue in guinea pigs was much
stronger with a high intake of vitamin C. The points on the graph show the strength of scar tissue in guinea pigs that had been given no vitamin C, 0.25 mg, 0.5 mg, 1 mg, and 2 mg per day. The scars had been formed during a seven-day period after the cuts, one-quarter inch long, had been made. The scar tissue is four times as strong for an intake of 2 mg per day as for 0.25 mg per day (Bourne, 1946). Similar results for humans have been reported by Wolfer, Farmer, Carroll, and Manshardt (1947).
and in addition millions of patients would be spared unnecessary suffering. It is deplorable that this way of decreasing suffering and saving money is being ignored by organized medicine and by many individual physicians and surgeons. It is not only by failing to act that many physicians and surgeons do harm to their patients. Often the patient who arrives in the hospital is prevented from receiving the supplementary vitamin G and other vitamins and minerals that he or she has been taking, just when they are needed the most. The value of vitamin G in promoting wound healing was recognized in the 1930s, when studies were made with guinea pigs, and it was recognized that the requirement of vitamin G for the synthesis of collagen might be the major mechanism of this action. I remember that in 1941 Dr. Thomas Addis, professor of medicine in Stanford Medical School, prescribed sup plementary vitamins and minerals for all his patients. Thirty years later I asked the physicians and surgeons in medical schools and hospitals that I was visiting to tell me what their practice was about prescribing vitamin C for their patients. One surgeon told me that he had all of his patients take 500 mg of vitamin C per day, but usually I received no response, and I formed the opinion that vitamin C was prescribed less in 1971 than in 1941. I think that during the last few years more physicians and surgeons have begun the routine prescribing of vitamin C, but I have not been able to obtain statistical information about this matter. From the reports made to
me by patients, however, it is clear that many physicians and surgeons now recognize the value of supplementary vitamin C. If you are injured or have to have a surgical operation, be sure to insist on being given the optimum amount of vitamin C. There have been many observations that vitamin C concentrates at the site of an injury and is destroyed. If supplementary amounts of the vitamin are not given to the patient, the concentrations in the plasma, serum, whole blood, and white cells drop to low levels. Crandon et al. (1961) in their study of 287 surgical patients found that the vitamin C concentration in the leucocytes and platelets (buffy coat) and in the plasma decreased after surgery by about 20 percent. Similar results have been reported by other investigators (Coon, 1962; Irvin and Chattopadhyay, 1978; McGinn and Hamilton, 1976). Mukherjee, Som, and Chatterjee (1982) found a large decrease in ascorbate concentration in the plasma and blood, over 50 per cent, after trauma or surgery for 40 patients and some increase in the concentration of the oxidation product dehydroascorbic acid. Sayed, Roy, and Acharya (1975) studied 1434 patients and found a decrease in leuko cyte concentration following surgery of 19 percent for the patients whose surgical wounds were not infected and by 30 percent for those whose wounds were infected. It was observed long ago that peptic ulcers are associated with a defi ciency of vitamin C (Ingalls and Warren, 1937; Portnoy and Wilkinson, 1938). The gastric juice in the stomach is acidic and corrosive. It contains enzymes such as pepsin to attack the proteins in the food and in this way to continue the process of digestion that was started in the mouth by chewing and by the action of the enzymes in the saliva. Since the walls of the stomach contain proteins, there is the possibility that the gastric juice might attack them. Sometimes the protective structures break down in some spot and the gastric juice begins its attack, causing an ulcer in the stomach (a gastric ulcer) or in the adjacent intestine (a duodenal ulcer). The formation of these ulcers can be initiated by aspirin, cortisone, cincophen, and other drugs, which sometimes cause gastric hemorrhage. Many later reports of vitamin C and ulcers have been published, show ing that an increased intake of the vitamin has both prophylactic and thera peutic value. A discussion of the evidence with references to the literature has been presented by Irwin Stone (1972). A pressure sore (bed sore, decubitus ulcer) is an ulcer overlying a bony prominence that has been under pressure from a bed, wheelchair, or other object. These ulcers plague paraplegics and debilitated persons. They are hard to handle, and surgical treatment is often needed. In 1972 Burr and Rajan reported their observations on ninety-one paraplegics and forty-one control subjects (patients without pressure sores), with the controls and the patients with pressure sores each divided into four
subgroups (male and female, smokers and nonsmokers). In each of the eight subgroups the concentration of vitamin C in the leukocytes was highest for the controls and lowest for the patients with pressure sores. Also in each of the six categories the concentration was much lower for the smokers than for the nonsmokers. A double-blind controlled trial with twenty surgical patients with pres sure sores was reported in 1974 by Taylor et al. Ten of the subjects, se lected at random, were given 1 g of vitamin C each day, and the other ten were given a placebo. After one month there was an average reduction in pressure-sore area by 84 percent for the vitamin-C patients, with six com pletely healed, and by 43 percent for the placebo patients, with three com pletely healed. The investigators point out that their results have high sta tistical significance in showing the acceleration of healing of pressure sores by 1 g per day of vitamin C. A larger intake should be even more effective. More than thirty years ago it was reported that vitamin C and other vitamins in large doses have much value in the treatment of burns (Brown, Farmer, and Franks, 1948; Klasson, 1951; Yandell, 1951). It is, of course, reasonable that vitamin G should help in this healing process because of its being required for the synthesis of collagen, which is a principal component of scar tissue and of skin. The investigators usually administered about 2 g of vitamin G per day, orally or by intravenous infusion, and in addition applied dressings of a 5 percent or 10 percent aqueous solution of the vitamin. Other vitamins were also administered in daily amounts 20,000 International Units (IU) of vitamin A, 20 to 50 mg of Bu 20 mg of B2, 150 to 250 mg of niacin, 2000 IU of vitamin D, and 1 mg of vitamin K. Excellent results in the treatment of burns with vitamin E, both orally and topically, have also been reported (Shute and Taub, 1969). Vitamin E also has value in converting keloids (hard irregular excrescences on the skin, often the result of burns) into skin of normal texture. Supplementary vitamin C has value in preventing and healing gastric ulcers and in the healing of wounds and burns. Intakes as small as 1 g per day have been found to have a significant effect. The optimum intake, of several grams per day, can be expected to be even more effective. Much suffering and loss of life can be prevented by the proper use of vitamin G. I remember that fifty years ago I asked one of my graduate students about the condition of his father, who had undergone abdominal surgery some time before. He said that his father was declining in health (and in fact died not long afterward), because the surgical incision would not heal. There is little doubt that he was deficient in vitamin G. I regret that I did not know enough about vitamin G at that time to enable me to suggest that he be given vitamin C and other vitamins. Now, fifty years later, there is no excuse for a surgical patient not to be given good amounts of supplementary vitamin G.
16.M
u s c u l a r
A c tiv ity
The function of the muscles in the human body is to do work, powered by the energy released by the oxidation of foods, especially the carbohydrates and fats. In doing work a muscle contracts, decreasing its length and in creasing its width in such a way as to keep its volume constant. Good health requires good muscular activity. It should be no surprise to the reader who has come this far to learn that vitamin C has a part in maintaining the integrity and function of muscle tissue. Muscle tissue contains 20 to 30 percent protein. The contractile material is the protein actomyosin, which is itself composed of two fibrous proteins, actin and myosin. The molecular mechanism of muscular contraction is now known, largely through the work of the British biologist H. E. Huxley. A muscle consists of myosin molecules that are aggregated into filaments with the head ends of the molecules pointing in two opposite directions. The actin molecules are attached to a plate, from which they extend on both sides. In an extended muscle the ends of the actin filaments just reach the ends of the myosin filaments. The end of a myosin molecule is attracted to the complementary regions on the surfaces of the actin mole cules by specific interatomic forces, and as a result the myosin filaments, in the course of contraction of the muscle, creep along down the channels between the actin filaments, with successive myosin molecules shifting from one actin molecule to the next.
In its contraction the muscle has done work. Energy must be supplied to break the bonds between the heads of the myosin molecules and the comple mentary regions of the actin molecules. This energy is supplied by the oxidation of foods, especially fats. The oxidation takes place inside the mitochondria, which are small structures inside the muscle cells and par ticipating in their metabolism. The energy of the oxidation is used to produce the high-energy molecules adenosine triphosphate (ATP) from adenosine diphosphate (ADP) and phosphate ion. The high-energy ATP molecules then diffuse into the contracted muscle and use their energy to change the structure of the actin and myosin complementary regions in such a way that they no longer attract one another, permitting the muscle to relax into its extended state. These regions then revert to their active struc tures and the muscle is ready to contract again, when instructed by a nervous impulse. One of the substances involved in muscular activity is carnitine. It is one of many orthomolecular substances in the human body—substances nor mally present and required for life. Its molecules are small, containing only twenty-five atoms, its formula being (CH3)3N +CH2CH(OH)CH2COO. It was discovered in 1905 by two Russian scientists, Gulewitsch and Krimberg, who were studying muscle. They found that the substance is present to the extent of about 1 percent in the juice from red meat, with a smaller amount in that from white meat, and named it from carnis, the Latin word for “flesh” or “meat.” It was then discovered that carnitine is required to move molecules of fat into the mitochondria, where they are oxidized to provide the energy of muscular activity. A molecule of carnitine in the cytoplasm outside the mitochondrion combines with a molecule of fat and a molecule of coenzyme A to make a complex that can penetrate the mitochondrion wall. Inside the mitochondrion, the complex liberates the carnitine, which can move outside to repeat its action of serving as a shuttle to carry more molecules of the fuel into the mitochondrion. The rate at which the fat is made available as fuel for the muscle is determined by the amount of carnitine in the muscle. This makes carnitine an important substance. We obtain some carnitine from various foods, especially red meat. This may explain why red meat has the reputation of increasing muscular strength and why beef extract, made from the soluble constituents of beef meat, was for a century a popular drink (beef tea). We are also able to synthesize carnitine from lysine, one of the amino acids that are present in the polypeptide chains of the many proteins in our bodies and that we obtain in good amount by digesting the proteins in our food. Studies on animals have shown that most of the carnitine has been synthesized by the animal from lysine, with only about one-fifth coming
from the food (Cederblad and Linstedt, 1976; Leibovitz, 1984). Similar studies have not been carried out for human beings, but there is the possi bility that many people would achieve greater muscular strength by an in crease in their carnitine levels. A gene mutation resulting in loss of the ability to convert lysine into carnitine has been reported by Engel and Angelini (1973). The patients are extremely fatigued and have extraordinary muscular weakness. For some patients the disease is controlled by a high intake, several grams a day, of L-carnitine (for references see Leibovitz, 1984). In his 1984 book about carnitine Brian Leibovitz discusses the results of his own studies and those of other investigators of the value of supplemen tary carnitine in improving strength, health, and athletic performance and in leading to decreased obesity. His recommended dietary intake of Lcarnitine is 500 milligrams (mg) per day. He also points out that there is some evidence that the mirror-image form, D-carnitine, which does not occur in nature, has been observed to have some toxic reactions. Only the L form is effective in increasing muscular power. Accordingly only half of a dose of the D,L mixture would be effective, and the other half might be harmful. I have found in the December 1984 issue of Prevention magazine three advertisements for D,L-carnitine and none for L-carnitine, but Leibovitz lists six companies that sell the pure L isomer. The optimum intake of vitamin C and of other vitamins and minerals might increase the amount of L-carnitine synthesized from lysine to obviate the need for any supplementary carnitine. The conversion of lysine to car nitine takes place through five successive biochemical reactions, each cata lyzed by a specific enzyme. The second and fifth of these reactions involve hydroxylation, for which vitamin C is needed. Accordingly the amount of carnitine that is made in the human body depends on the intake of vitamin G. This explains the fact that sailors who were developing scurvy showed lassitude and muscular weakness as the first signs of their disease, and why Ewan Cameron’s debilitated cancer patients in Vale of Leven Hospital said “But Doctor, I now feel so strong” a few days after they began their intake of 10 grams of vitamin C per day. The other nutrients involved in the conversion of lysine to carnitine are the amino acid methionine, vitamin B6, and iron. There are muscle fibers everywhere in the body. Leukocytes swim through the contraction of their actin-myosin fibrils. The heart beats through muscular contraction. The role of vitamin C in benefitting the heart is the subject of the next chapter. Much backache, low-back pain, is caused by muscular weakness and by deterioration of the collagenous substances in the joints. Nearly every per son suffers occasionally from back pain, sometimes caused by too heavy a
load on the back muscles, and about 50 percent of people more than sixty years old have chronic back trouble. Surgery is needed in case of a ruptured intervertebral disk or certain other conditions. The preceding discussion of vitamin G in relation to both collagen and muscle suggests that a high intake of this vitamin might often provide significant control of back problems. In 1964 Dr. James Greenwood, Jr., clinical professor of neurosurgery in Baylor University College of Medi cine, reported his observations on the effect of an increased intake of ascor bic acid in preserving the integrity of intervertebral discs and preventing back trouble. He recommended the use of 500 mg per day with an increase to 1000 mg per day if there was any discomfort or if work or strenuous exercise was anticipated. He said that evidence from most patients indi cated that muscular soreness experienced with exercise had been greatly reduced by these doses of ascorbic acid, but it increased again when the vitamin was not taken. He concluded, from observation of more than five hundred cases, that “it can be stated with reasonable assurance that a significant percentage of patients with early disk lesions were able to avoid surgery by the use of large doses of vitamin G. Many of these patients after a few months or years stopped their vitamin G and symptoms occurred. When they were placed back on the vitamin the symptoms disappeared. Some, of course, eventually came to surgery” (Greenwood, 1964). Green wood has informed me when he visited me at my home in California that he has continued to find vitamin C helpful in controlling problems with the lower back. Larger intakes than the 500 or 1000 mg per day that he first recommended have even greater value.
17.T h e
H
e a r t
Heart disease (rheumatic fever and rheumatic heart disease, hypertensive heart disease, ischemic heart disease, acute myocardial infarction, and other forms) is the principal cause of death in the United States, responsible for about 48 percent of all deaths, with related diseases (stroke, hypertension, atherosclerosis, and other diseases of arteries, arterioles, and capillaries) responsible for another 10 percent. In 1986 about 1,400,000 people in the United States will die of these diseases. I believe that the death rate from these diseases at every age could be decreased greatly, probably cut in half, by the proper use of vitamin C and other nutrients. There is no doubt that heart disease is related to the diet. In the 1976 congressional hearings on the relation between diet and disease the nation’s top health officer, Dr. Theodore Cooper (Assistant Secretary for Health in the Department of Health, Education and Welfare) stated that “While scientists do not yet agree on the specific causal relationships, evidence is mounting and there appears to be general agreement that the kinds and amount of food and beverages we consume and the style of living common in our generally affluent, sedentary society may be the major factors asso ciated with the cause of cancer, cardiovascular disease, and other chronic illnesses.” About thirty years ago it was recognized that there is a correlation be tween the incidence of heart disease and the amount of cholesterol in the
blood. Cholesterol is a lipid, soluble in fats and oils, with chemical formula C27H460 . It is manufactured in all cells of animals, especially the liver, but is not found in plants. Human beings synthesize about 3000 to 4000 milli grams (mg) per day and receive a somewhat smaller amount in their food, mainly from eggs and animal fat. Cholesterol is found in all the tissues of the human body, especially the brain and spinal cord. People with a high percentage of cholesterol in the blood have an increased incidence of cardio vascular disease. High blood cholesterol was found to cause fatty deposits in blood vessels throughout the body, narrowing these vessels and reducing the flow of blood through them. The decreased blood flow can lead to heart disease and diseases of the circulatory system. It was recommended by the medical authorities that people decrease their intake of eggs and animal fat. For twenty years there was no change in the mortality from cardiovascular diseases in the United States. Since 1970 there has been some decrease, but it is not known whether it is the result of a change in diet or some other cause, perhaps the larger increase in the intake of supplementary vitamin C and other vitamins since 1970. Later studies have shown that there are several correlations between cardiovascular disease and constituents of the blood. Most of the cholesterol in the blood is not free; instead, it is attached to the molecules of certain serum proteins that have an affinity for fatlike substances, forming lipopro tein molecules. Some of these molecules have a low density: they are called beta-lipoprotein, or low-density lipoprotein, and those with higher density are called alpha-lipoprotein, or high-density lipoprotein. The two kinds of lipoproteins can be separated by spinning a sample of blood in an ultra centrifuge, and their amounts can be measured. For many years most of the emphasis has been on the cholesterol in the low-density lipoprotein or on the total cholesterol, which is more easily measured, and the high-density lipoprotein was usually ignored. It has now been found that the incidence of cardiovascular disease tends to increase with increase in the amounts of total blood cholesterol, low-density lipoprotein (LDL) cholesterol, and triglycerides, and to decrease with the amount of high-density lipoprotein (HDL) cholesterol. These correlations can be understood from the func tions of LDL and HDL. LDL carries cholesterol through the bloodstream, where it may attach itself to cells and form atherosclerotic plaques, whereas HDL picks it up and carries it to the gall bladder, where it is converted into bile acids that are then eliminated into the intestines through the bile duct. The amounts of cholesterol in the blood and tissues are determined by the rate at which it is synthesized in the liver (from acetate and other precursors), the rate at which it is obtained from food, the rate at which it is
converted into bile acids and excreted into the intestines, and the rate at which the bile acids are reabsorbed in the lower bowel and then recon verted into cholesterol. A steady state is set up between the rate of destruc tion (conversion to bile acids) and the other three rates. All of these rates are affected by the genotype of the person, the nature of the diet, and other factors. We see that it should be possible to change the steady-state level in the blood by varying any one of these four rates. An interesting and important study of this sort, with use of a drug, cholestyramine resin, was completed by the National Heart Institute in 1984. Cholestyramine resin is an artifi cial macromolecular substance (consisting of very large molecules) that is insoluble in water and when taken by mouth is retained in the feces and then eliminated. It has the property of combining with bile acids and thus preventing their reabsorption into the blood and reconversion into choles terol. In this way its ingestion leads to some decrease in the amount of cholesterol in the body. The study, which took ten years, cost $150 million. I think that it was worth-while for the National Heart Institute to spend this amount, because the study gave a definite result, the amount of benefit that we might expect from stopping the reabsorption of the bile acids in the lower bowel. In comparison with the cost of medical treatment of patients with heart dis ease, more than $100 billion per year, the cost of the investigation was trivial. Each of the 1900 cholestyramine patients, chosen by lot from the 3800 men in the study, was supposed to take a spoonful (4 grams [g]) of the resin granules six times per day. The 1900 controls in the double-blind study were supposed to take the same amount, 24 g per day, of another resin that does not combine with the bile acids. Compliance in each group was about two-thirds, an average of 16 g of resin each day. I am not astonished by the low compliance; it is a nuisance to have to take a spoonful of granules six times a day, for years, especially when there are occasional side effects of constipation, diarrhea, and nausea. In its principal finding, this study showed that the cholestyramine sub jects had an average lowering of total blood cholesterol by 8.5 percent more than the controls, and their death rate from heart disease was 25 percent less. The investigation of the effect of cholestyramine resin provides what seems to be a reliable value of the effect of reducing blood cholesterol. In this study it was found that the percentage decrease in the death rate from heart disease was three times the percentage decrease in the cholesterol level. In December 1984 a panel of experts convened by the National Institutes of Health (NIH) issued a report that included the recommendation that
adults thirty years old or older with total cholesterol levels 240 mg per deciliter or more, younger adults with levels above 220 mg per deciliter, and children with levels above 185 mg per deciliter take steps to reduce the level, through changing the diet or by cholesterol-lowering drugs. The drugs may have serious side effects, and changing the diet has limited value. The 1984 panel of the National Institutes of Health recommended de creasing the amount of eggs and animal fat in the diet to a cholesterol intake of 250 to 300 mg per day. Also, in the 1977 report “Dietary Goals for the United States” prepared by the staff of the Select Committee on Nutrition and Human Needs, U.S. Senate (Senator George McGovern, chairman), one of the six dietary goals is “Reduce cholesterol consumption to about 300 mg per day.” But it has been known since 1970 from the multimillion-dollar Framingham study of diet in relation to heart disease that restricting the intake of cholesterol does not reduce the cholesterol level in the blood. In this study the men and women had average cholesterol intakes of 702 and 492 mg per day, respectively. (One egg provides about 200 mg.) The average serum concentrations for men and women with higher than average intakes were found to be 237 and 245 mg per deciliter, respectively, and those for men and women with lower than average intakes were nearly the same, 237 and 241 mg per deciliter. Thus there was no effect of decreased intake of cholesterol on the concentration in the blood. The explanation of this rather surprising result is that human beings, of course, synthesize cholesterol in their own cells, in the amount of around 3000 or 4000 mg per day, and there is a feedback mechanism that decreases the rate of synthesis of the substance when the intake is increased. It is regrettable that Senator McGovern’s committee and the NIH panel should be giving unreliable information and advice to the American people such as to tend to deprive them of a reasonable amount of such good foods as eggs, meat, and butter. The fat-in-food-cholesterol-in-the-bloodstream idea is dying hard, as noted in Chapter 6. During the last decade it has become increasingly evident that the great hope of thirty years ago that heart disease could be controlled by limiting the intake of saturated fat (as in meat and butter) and cholesterol (in meat and eggs) and increasing that of unsaturated fat, especially polyunsaturated fat (margarine, certain vegetable oils) had failed. A thoughtful study of the evidence was published in the New En gland Journal of Medicine in 1977 by Dr. George V. Mann of Vanderbilt University School of Medicine. In his opening paragraph he writes that “Foundations, scientists, and the media, both lay and scientific, have pro moted low fat, low cholesterol, polyunsaturated diets, and yet the epidemic continues unabated, cholesteremia in the population is unchanged, and cli nicians are unconvinced of efficacy. . . . And yet the oil and spread industry advertises its products with claims and promises that make these foods seem
like drugs. The vibrant certainty of scientists claiming to be authorities on these matters is disturbing.” He mentions that in the 1950’s the diet-heart enthusiasts exerted pressure on physicians, who “were overwhelmed by this assault, arising from both their waiting rooms and their professional jour nals. A low fat, low cholesterol diet became as automatic in their treatment advice as a polite goodbye.” In his 1976 article “Is It True What They Say About Cholesterol?”, Dr. Mark D. Altschule discussed the hypothesis that the ingestion of foods, such as eggs, that contain cholesterol increases the risk of heart disease. He said that “Today an awesome collection of powerful agencies, public and private, put forward statements that assert or imply its truth.” He then discussed eight clinical trials, carried out in the United States, England, and Scandinavia and published between 1965 and 1972. Most of these studies failed to show that a change in the amount of cholesterol in the diet had any significant effect on the incidence of heart disease. These results and other similar results have caused Mann and others to reach the conclusion that the emphasis on the intake of fats and cholesterol during the last thirty years has been misguided and fruitless. The way is now clearing for the recognition of the decisive work of John Yudkin and of those who have followed up on his demonstration (Chapter 6) that it is the increase in the consumption of the sugar sucrose that has brought on the pandemic of heart and circulatory disease in the prosperous industrial countries of the world. Along with the reduction of sucrose in the diet there is another measure everyone can take to reduce the risk of heart disease from elevated choles terol levels in the blood: that is the intake of supplemental vitamin C. An increased intake of vitamin C decreases total cholesterol, LDL cholesterol, and triglycerides, and increases HDL cholesterol; in all these ways it helps protect against heart disease. Total cholesterol is regulated by vitamin C in several ways. Ginter (1973) in Czechoslovakia showed that a high intake of the vitamin in creases the rate of removal of cholesterol from the blood by its conversion into bile acids, which are excreted with the bile into the intestines (many additional references are given by Turley, West, and Horton, 1976). This conversion involves hydroxylation reactions, for which ascorbate is in gen eral required. A good dose of vitamin C taken before breakfast can act as a laxative and speed up the elimination of the waste material in the bowel, thus decreasing the reabsorption of the bile acids and their reconversion to cholesterol. A high-fiber diet probably also has value because of a similar effect. The discovery that a high HDL level helps prevent cardiovascular dis ease was made long ago (Barr, Russ, and Eder, 1951) and has been veri fied in many recent studies, such as the Tromso Heart Study in Norway
(Miller et al., 1977) and a study in Hawaii (Rhoads, Gullrandsen, and Kagan, 1976). In several recent studies it has been verified that an in creased intake of vitamin C increases the HDL level (Bates, Mandal, and Cole, 1977; Harte et al., 1984; Glover, Koh, and Trout, 1984). In an early study by I. A. Myasnikova in 1947 she reported that serum cholesterol concentrations in humans with high cholesterol could be low ered by the increased intake of vitamin C. Ginter found in one study with patients with average initial plasma cholesterol level of 263 mg per deciliter that intake of 1 g of vitamin C per day resulted in three months in an average decrease in this level by 10 percent and a decrease in triglycerides by 40 percent (Ginter, 1977). In a study of patients with an average initial cholesterol level of 312 mg per deciliter who were given 3 g of vitamin C for three weeks the decrease in the cholesterol level was 18 percent and that in triglycerides was 12 percent (Fidanza, Audisio, and Mastrovacovo, 1982). Little change, however, is observed for men and women with low or normal cholesterol values, 132 to 176 mg per deciliter, by taking 1 or 3 g of the vitamin per day for four to twelve weeks (Johnson and Obenshein, 1981; Kahn and Seedarnee, 1981; Elliott, 1982). The explanation of this difference has been discussed by Ginter through a study of 280 men and women divided into fourteen groups on the basis of the initial cholesterol level (Ginter, 1982). When 300 to 1000 mg of vitamin G was given to the subjects, their average cholesterol levels changed by amounts ranging from + 5 percent to —19 percent, as shown in the illustration on page 151. The heavy line in the figure corresponds to the linear regression line given by Ginter. His conclusion, which agrees with the results of other investigators, is that vitamin C has little effect on the cholesterol level in the normal range, below about 200 mg per deciliter, but has a large effect in decreasing high levels by 10 to 20 percent. If we accept the 1984 statement by the National Institutes of Health Panel that for each 1 percent decrease in the cholesterol level there would result a 2 percent decrease in cardiovascular mortality or the chole styramine result of 8.5 percent decrease in cholesterol associated with a 25 percent decrease in cardiovascular mortality, we may conclude that an in creased intake of vitamin C might lead to a 20 to 60 percent decrease in the mortality rate for the people at risk. There is evidence from epidemiological studies of the health of popula tions to support this conclusion. These studies have shown quite clearly that a diet including fresh fruits and vegetables is beneficial to the health. The effort has been made to analyze the diets in relation to their effect on health in order to determine what nutrients in the ingested foods are most important in decreasing the death rates. Of all of the twenty-five factors considered in the San Mateo County study conducted by Chope and
Breslow, the intake of vitamin C was found to be the most important in decreasing the death rate. The people in the study who had been receiving 50 mg or more per day had an age-corrected death rate only 40 percent of that of the people who had been receiving less than 50 mg per day. Most of the deaths, as with the population as a whole, were from cardiovascular disease. An epidemiological study by Knox of a very large population in England gave similar results (1973). He found, as had been known before, that a high intake of calcium is associated with protection against ischemic heart disease and cerebrovascular disease and also that a still greater protective effect—greater than that for any other factor—is associated with an in creased intake of vitamin C. In an attempt to obtain evidence about the mortality rate among users of vitamin supplements a prospective six-year study was made of 479 elderly California respondents to a 1972 question naire carried in Prevention magazine (Enstrom and Pauling, 1982). The subjects had an average daily intake of about 1 g of vitamin C, as well as larger than usual intakes of vitamin E and vitamin A, and they followed other good health practices. Relative to the expected 1977 rate for U.S.
whites, their standardized mortality rate for cardiovascular diseases (which caused 58 percent of all deaths), was 75 percent for males, 46 percent for females, 62 percent for both sexes. The values for all causes of death were 78, 54, and 68 percent of the expected national rate for that year. These observations indicate that these health-conscious elderly Californians have a life-style, including taking supplementary vitamins, that is correlated with a 38 percent decrease in cardiovascular mortality and a 21 percent decrease in mortality from other causes. These epidemiological studies and other similar ones strongly support the conclusion that a significant amount of protection against cardiovascu lar disease can be achieved by increasing the intake of vitamin C above the 60 mg Recommended Daily Allowance of the U.S. Food and Nutrition Board. Much evidence has been reported recently about the value of eating fish, either lean fish or fat fish, in decreasing the incidence of coronary heart disease. In one study (Kromhout et al., 1985) it was found that subjects who ate no fish had an age-standardized death rate from coronary heart disease 2.5 times as great as that for subjects who ate 1 ounce (28.3 grams) or more per day. Part of the effect can be attributed to the fish oils (Phillipson et al., 1985; Lee et al., 1985). Hundreds of millions of dollars have been spent by the National Insti tutes of Health, the American Heart Association, and other agencies in support of studies of cardiovascular disease in relation to LDL and HDL cholesterol, triglycerides, saturated fats, and unsaturated fats. Very little attention has been paid to vitamin C and other vitamins. I think that these agencies have been betting on the wrong horse. It is fortunate that vitamin C is not a drug—it is an orthomolecular substance, normally present in the human body and required for life, and it has extremely low toxicity. You do not need to have a physician’s prescrip tion or the approval of the medical establishment to use it in the best way to improve your health and to prevent heart disease. Your knowledge may even be greater and your judgment better than theirs.
18 Cardiovascular Disease
For the control of the atherosclerotic pathology that underlies the cardio vascular diseases in their several manifestations there is another vitamin that has demonstrated its efficacy, administered alone and with vitamin C. This is vitamin E (tocopherol), one of the fat-soluble vitamins. It was discovered in 1922 by Herbert M. Evans, professor of biochemistry in the University of California, and his coworker Katherine Scott Bishop. They showed that it is necessary for full health in rats, but the question of whether or not it is needed for humans was not settled until recently. Only in 1968 did the U.S. Food and Nutrition Board finally decide that it is essential to human nutrition and set the recommended daily allowance for an adult at 30 international units (IU). By 1980, however, the Recommended Daily Allowance (RDA) had been reduced by the board to 10 IU. The board has described the basis of its decision in the following words: Inasmuch as there is no clinical or biochemical evidence that vitamin E status is inadequate in normal individuals ingesting balanced diets in the United States, the vitamin E activity in average diets is considered satisfactory. . . . The values [of the RDA] in the table should be considered as average adequate intakes in the United States, but the adequacy of these intakes will vary if the PUFA
(polyunsaturated fatty acid) content of the diet deviates significantly from that which is customary. . . . Evidence that normal persons benefit from supplements above the recommended allowance is largely subjective. The Food and Nutrition Board has accordingly rejected all of the evi dence that will be presented here—or perhaps it considers that people who may die of cardiovascular disease or have other problems that are helped by vitamin E are not “normal persons.” Since more than half of all people in the United States die of cardiovascular disease, this attitude seems to me to be irrational. As late as 1980 the board had not learned about the difference between the minimum intake and the optimum intake of an essential nutrient. During the last sixty years a keen controversy has persisted over the possible value of vitamin E in far larger amounts than 10 IU per day for controlling or curing many serious diseases, including coronary heart dis ease and peripheral vascular disease. The controversy centers around the Canadian physician Dr. R. James Shute and his two sons, Dr. Evan V. Shute and Dr. Wilfrid E. Shute, who had begun using vitamin E in the treatment of disease in 1933. Their claims of success were contradicted by many other physicians, especially in the years around 1948, and for thirtyseven years since then the stand taken by nearly all medical authorities has been that vitamin E in amounts greater than the RDA of 10 IU has no value in improving health or in preventing or controlling disease. It is my opinion that the authorities are wrong about vitamin E, as they were about vitamin C. When vitamin E was isolated from wheat germ oil in 1936, it was found to be a mixture of several similar substances, which are called alphatocopherol, beta-tocopherol, gamma-tocopherol, delta-tocopherol, and so on. Each of these can occur as the D form or the L form. They all have biological activity and antioxidant power but in different amounts. Vitamin E capsules often contain pure DL-alpha-tocopheryl acetate, for which 1 milligram (mg) equals 1 IU. They may, however, contain a mixture of tocopherols or their esters, in relative amounts such as to give the biological effect corresponding to the number of IU stated on the label. The various biological and antioxidant effects do not change in quite the same way from one tocopherol to another, so that the number of IU is only a rough mea sure of the activity of vitamin E. Wilfrid Shute recommended that alphatocopherol (or alpha-tocopheryl acetate) be used in controlling heart dis ease, but the other tocopherols taken in the same dosage (measured in IU) probably have essentially the same value. The relative vitamin-E activities
of the several tocopherols have been determined by animal studies, espe cially the effectiveness in permitting normal reproduction in the rat. Pure vitamin E is an oil, practically insoluble in water but soluble in oils and fats. It is found in many foods (butter, vegetable oils, margarine, eggs, fruits, and vegetables). In 1956 it was discovered that patients in a state hospital who for several years had lived on a diet containing only 3 IU of vitamin E showed an increased fragility of their red blood cells, caused by oxidation of the unsaturated fatty acids in the cell membrane. Vitamin E acts as an antioxidant and prevents or reverses the oxidation, being itself oxidized in the process. Vitamin C, which is also an antioxidant, can re store the vitamin E to its original state. A diet high in unsaturated fatty acids, especially the polyunsaturated ones, can destroy the body’s supply of vitamin E and cause muscular le sions, brain lesions, and degeneration of blood vessels. Care must be taken not to include a large amount of polyunsaturated oil in the diet without a corresponding increase in the intake of vitamin E. In 1950 the Council on Pharmacy and Chemistry of the American Medi cal Association published a report on vitamin E, including the following statements: More than three years ago stories appeared concerning a remarkable new treatment for patients with circulatory disease. The treatment was said to have been discovered by some investigators in London, Canada. It was alleged that large doses of vitamin E, or alpha tocopherol, could effect remarkable recoveries in patients with a wide variety of cardiovascular disorders who had not been benefitted by more orthodox therapy. . . . The first announcement of the possible effectiveness of alpha tocopheryl acetate in coronary heart disease appeared as a letter, signed by A. Vogelsang and E. V. Shute, in Nature (1946, 157:772). Subsequently a series of articles appeared in the Medical Record (Surgery, Gynecology, and Obstetrics, 1948, 86:1) that varicose ulcers, thrombophlebitis, early gangrene of the extremities, thromboangiitis obliterans, and cerebral thrombosis respond to vitamin E therapy. The disease most recently reported by Vogelsang of the Shute Institute to respond to vitamin E therapy is diabetes (Medical Record, 1948, 161:363; Journal of Clinical Endocrinology, 1944, 8:883). . . . The lay press already has devoted considerable space to the claimed virtues of vitamin E. . . . It is regrettable that the hopes of sufferers from heart disease and other cardiovascular conditions, as well as those of countless diabetic persons, should be falsely raised by unbridled enthusiasm.
This attitude of unhealthy skepticism has persisted for thirty-five years. In 1977 the leading U.S. authority on old-fashioned nutrition, Dr. Jean Mayer, president of Tufts University, stated that “Because of the variety of the deficiency signs in various animals, enormous doses of vitamin E have been tried in a great many human diseases, from habitual abortion to heart disease and muscular dystrophy. The experiments were not a success. So doctors went back to the position that we need vitamin E, but only in moderate amounts,” (Mayer, 1977.) Mayer also describes the use of large amounts of vitamin C to control the common cold as a “fad,” started by me, and suggests that no one should ever take more than the RDA, quoting several of the fallacious arguments discussed in Chapter 27. Harmful side effects from very large doses of vitamin E have not been reported. In this respect it differs from the various drugs, such as aspirin (to mention one of the less dangerous), that are widely used in treating the diseases for which the Shutes claim that vitamin E is valuable. The fact that vitamin E is safe and the fact that the Shutes claim that it has value in treating coronary heart disease and several other diseases should have caused the skeptical medical authorities to carry out a thorough investiga tion by means of a number of large double-blind trials, in which patients in one group, selected at random, receive the vitamin, and those in another group receive a placebo. But in fact these thorough investigations have not been carried out, thirty-nine years after the original claims were made. It has been argued that it was the duty of the Shutes to carry out these double-blind studies themselves, but the basic principles of medical ethics have made it impossible for them to do so. They themselves were convinced of the great value of vitamin E in 1946. A physician has the moral duty to give to each patient the treatment that he or she believes to have the greatest chance of healing the patient. Hence it was the duty of the Shutes to continue to use vitamin E for all their patients with the diseases that they had found vitamin E to control. To have kept this beneficial treatment from half of their patients would have been immoral. It would not be immoral, however, for a skeptic, a physician who be lieves that vitamin E has no value, to carry out a double-blind study of this sort. It is not the Shutes but rather the other members of the medical profession who have failed in their duty, by not having made extensive studies of vitamin E, when there was strongly suggestive evidence that this nontoxic, safe, natural substance has some value, probably even great value, in controlling diseases that each year cause about 200 million patient-days of bed disability and 1 million deaths in the United States. In addition to many papers published in medical journals since 1946, the Shutes have described their methods and results in two books, Vitamin E for Ailing and Healthy Hearts} by Wilfrid E. Shute and Harold J. Taub
(1969) and The Heart and Vitamin E, by Evan Shute and his staff (1956, 1969). The diseases discussed in separate chapters of these books include coronary and ischemic heart disease and the accompanying angina, rheu matic fever, acute and chronic rheumatic heart disease, high blood pres sure, congenital heart disease, peripheral vascular disease, arteriosclerosis, Buerger's disease, varicose veins, thrombophlebitis, arterial thrombi, indo lent ulcer, diabetes, kidney disease, and burns. They believe that vitamin E in doses of between 50 IU and 2500 IU per day has value in treating all of these diseases. The vitamin E is given by mouth. An ointment (3 percent vitamin E in petroleum jelly) is also used for burns and ulcers and some forms of pain. Wilfrid Shute states that in the twenty-two years before 1969 he had treated thirty thousand cardiovascular patients. The records of hundreds of them have been published. For the most part, the only “control cases” have been provided by the record of the patient himself before he began vitamin E. For example, one patient, an elderly physician with diabetes, had severe ulceration and impairment of the circulation in one leg, so serious as to indicate that amputation was necessary. The leg was amputated. Ulcer ation and impairment of the circulation developed in the other leg. He then learned of the Shutes. Vitamin E was administered. After some months the other leg was healed, and amputation was avoided. Another patient, age fifty-eight in 1951, had a coronary occlusion with posterior infarction. After two weeks in the hospital he was sent home but was not able to work. After six months he was seen by Wilfrid Shute, who placed him on 800 IU of vitamin E per day. Within ten weeks he was free of symptoms and had returned to work. Seventeen years later he had an attack of auricular fibrillation, which was soon controlled with oxygen. He was in good condition in 1968, at age seventy-six. There are scores of such case histories in the books. They do not consti tute proof, but there is no doubt that Wilfrid Shute and Evan Shute were convinced that vitamin E is the most important substance in the world. 1 confess to having the same feeling about vitamin C. Some years ago I was prompted by an article in Consumer Reports to check the published studies of vitamin E and heart disease. Consumer Re ports is a publication that purports “to provide consumers with information and counsel on consumer goods and services, to give information on all matters relating to the expenditure of the family income, and to initiate and to cooperate with individual and group efforts seeking to create and main tain decent living standards.” It has millions of readers. For many products its advice may be good, but for the vitamins it is completely unreliable. It makes no tests of vitamins but relies upon some anonymous authority whose judgment seems to me to be untrustworthy.
In its January 1973 issue, Consumer Reports had an article entitled “Vitamin E: What’s Behind All Those Claims for It?” The writer of the article gave a long list of diseases for which therapeutic claims for vitamin E have been made (those mentioned by Wilfrid and Evan Shute, as listed above, and also acne, aging, and others) and concluded with the statement, “We have been unable to unearth valid scientific evidence that vitamin E helps any of the long list of ailments catalogued on page 62.” He then wrote that the only therapeutic use of vitamin E established by a well-controlled clinical trial is the treatment of hemolytic anemia in certain premature babies and that some doctors prescribe it as a precautionary measure in a few relatively rare diseases involving fat absorption. The article concluded, “Otherwise, the use of vitamin E as a dietary supplement or as a medication for common ailments is at best a waste of money. But far more serious, it could lead to postponing proper medical treatment in favor of worthless self-medication. And the cost of that may be incalculable.” The conclusions are said to be based on published reports of various trials of vitamin E by physicians, to which reference is made in the article. I made a careful examination of every one of these published reports, and I found that they do not justify the conclusion reached by Consumer Reports. My conclusion is that their medical authority, the writer of the article, lacked the ability to evaluate the evidence properly. Consumer Reports had listed several studies of vitamin E and coronary heart disease that had been carried out around 1949. All were said to have given negative results, refuting the claims made by the Shutes. I decided that the studies were all unreliable because they used too small an amount of the vitamin or used it for too short a time or for some other reason. For example, the study that is described as “perhaps the most sophisticated” was carried out by Donegan, Messer, Orgain, and Ruffin, of Duke Univer sity School of Medicine {American Journal of the Medical Sciences 217 [1949] :294). It involved twenty-one patients with cardiovascular disease, who were followed for five to twenty months. During alternate months each patient received vitamin E (150 to 600 IU per day) or a placebo. The patients were seen once a month. There was little difference in their condi tion after a month of vitamin E than after a month of placebo. It is known, however, that two or three months of vitamin E intake is needed for it to become effective. It is stored in the fat, and depletion of the body store occurs only slowly. Hence, the patients would not have changed very much in their store of vitamin E during the alternate months. This study, like the others, does not provide any refutation of the claims made by the Shutes. Dr. Alton Ochsner, the great heart surgeon who died in 1981, published several papers on his success in treating blood clots (thromboembolism and
thrombophlebitis) with vitamin E (Ochsner, DeBakey, and DeCamp, JAMA 144 [ 1950] :831; Ochsner, New England Journal oj Medicine 271 [1964] :4). Ochsner stated: “In all [surgery] patients in whom venous thrombosis [a blood clot in a vein] might develop, for a number of years we have routinely prescribed alpha tocopherol (vitamin E) 100 international units, three times a day, until the patient is fully ambulatory. . . . Alpha tocopherol is a potent inhibitor of thrombin [blood clotting factor] that does not produce a hemorrhagic tendency [as anticoagulant drugs tend to do] and therefore is a safe prophylactic against venous thrombosis.” Another piece of testimony was overlooked by Consumer Reports. This is the work of Dr. Knut Haeger of the Department of Surgery of Malmo Hospital, Sweden, who described his observations of 227 patients with peripheral occlusive arterial disease (1968). Of these patients 104 (average age 60.0 years) received 300 to 600 IU of vitamin E per day, with no other treatment, and 123 (average age 59.4) received either vasodilators, antipro thrombin, or multivitamins. There were no significant differences among the groups of patients given the last three different treatments. After two to seven years of observation, several differences were observed between the vitamin E patients and the other patients. Nine of the vitamin E patients died during the study, and 19 of the other group (8.7 percent versus 15.4 percent). One of the 95 surviv ing vitamin E patients had to have a leg amputated, and 11 of the 104 surviving patients of the other group (1.05 percent versus 10.58 percent; statistically significant at the 99-percent level of confidence.) The patients with peripheral or occlusive arterial disease after walking some distance suffer from sharp pains in the calves of the legs, because of an insufficient supply of oxygen to the muscles. Of the vitamin E patients, 75 percent in creased their walking distance by 50 percent, as compared with 20 percent of the other patients; 38 percent of the vitamin E patients more than dou bled their walking distance, as compared with only 4 percent of the other patients. The subjective feeling of improvement was much greater for the vitamin E patients than for the others. A number of other studies have given similar results. Boyd and Marks (1963) reported on 1476 patients with general atherosclerosis who had been treated with vitamin E for ten years. They found that the ten-year survival rate for these patients was higher than that found in any similar studies of patients who had not received vitamin E. My conclusion from the evidence summarized above and other reports in the medical literature, developed by able physicians other than the Shutes, is that there is no doubt that vitamin E has great value in controlling peripheral vascular disease, which often occurs together with heart disease and with diabetes, and also in preventing and treating blood clots (thromboembolism and thrombophlebitis). In addition, I believe that there
are sound arguments that support the claims made by the Shutes about the value of vitamin E for preventing and controlling coronary heart disease and other diseases. Haeger pointed out that the sharp pains in the calves of the legs that are experienced by patients with peripheral occlusive arterial disease after they have walked some distance are analogous to the sharp heart pains (angina) of patients with coronary heart disease. In each instance the pain results from a deficiency of oxygen—the working muscle has used up the oxygen faster than it can be brought to the muscle of the leg or heart through the clogged arteries. There is no doubt that the muscle pain is relieved by vitamin E (as are also the muscle cramps that some people experience). It is, accordingly, reasonable that the angina of the patient with heart disease would also be relieved by vitamin E, as described by Wilfrid Shute and Evan Shute in their books. It was recognized more than fifty years ago that a low intake of vitamin E leads to muscular dystrophy, a disorder of the skeletal muscles character ized by weakness similar to that caused by a deficiency of vitamin C (the studies of vitamin E and muscular dystrophy have been discussed by Pappenheimer, 1948). The difficulty in walking experienced by patients with peripheral occlusive arterial disease may result in part from a low vitamin-E concentration in the muscles and in part from a decreased rate of delivery of oxygen to them. The damage to the muscles when vitamin E is in short supply may be the result of oxidation of the unsaturated lipids, which are protected by the fat-soluble antioxidant vitamin E when it is present in sufficient concentrations. Several kinds of hereditary muscular dystrophies are known. For the most part their nature is not thoroughly understood, and there is no specific therapy recommended for them. Myasthenia gravis is treated by inhibitors of cholinesterase, corticosteroids, and surgical removal of the thymus gland. The medical authorities do not mention the possible value of vitamins in controlling muscular dystrophies. The evidence about the involvement of vitamin E and vitamin C as well as B6 and other vitamins in the function ing of muscles suggests that the optimum intakes of these nutrients should be of value to the patients. So far as I know, no careful study of an in creased vitamin intake for patients with hereditary muscular dystrophy has been reported. Vitamin E, the fat-soluble antioxidant vitamin, and vitamin C, the water-soluble antioxidant vitamin, collaborate in protecting the blood ves sels and other tissues against damage by oxidation. They slow down the process of deterioration of the body with the passage of time and help to prevent cardiovascular disease. They have value as an adjunct to appropri ate conventional therapy in the treatment of cardiovascular disease and other diseases.
In this book I have restricted my discussion almost exclusively to vita mins and other orthomolecular substances, with only occasional mention of drugs. I make an exception in this chapter to discuss a nonorthomolecular procedure—EDTA (ethylene diaminetetra-acetic acid) chelation prophy laxis—for atherosclerosis and the consequent diseases of the heart and pe ripheral circulatory system. One reason is that this prophylactic treatment seems to me to have a quite rational scientific basis, and the evidence of its value seems to me to be strong. The other reason is that most people would neither learn the truth about it nor receive good advice from their physi cians. Most physicians have heard about EDTA treatment, but advise against it on the basis of some false ideas, as discussed below. EDTA is used widely in analytical chemistry and chemical industrial processes, such as dyeing and the manufacture of soaps and detergents, where even very small concentrations of heavy metal ions in the water interfere with the reactions. It acts by combining strongly with these ions and thus sequestering them. This process is called chelation. EDTA is used in medicine, with approval by the Food and Drug Ad ministration, for treatment of persons poisoned with cadmium, chromium, cobalt, copper, lead, manganese, nickel, radium, selenium, tungsten, ura nium, vanadium, or zinc. It is usually administered by slow intravenous infusion of a solution containing 3 grams (g) of the calcium disodium salt. The poisonous metal ions combine more strongly with EDTA than with calcium ion and replace it in the complex and are then eliminated in the urine. EDTA also has value in helping to control cardiovascular disease, in cluding atherosclerosis, occlusive arterial disease, and heart disease result ing from a decreased supply of oxygen to the heart muscles. For this pur pose a solution of 3 g of sodium EDTA in 500 milliliters (ml) of Ringers solution, normal saline solution, or dextrose solution, often with some added sodium ascorbate, is administered by intravenous infusion over a period of three hours. The usual course of prophylactic treatment consists of twenty such infusions, usually two per week for ten weeks. There is evidence that such a treatment helps to eliminate atheromatous plaques. In the development of atherosclerosis the first step consists of laying down a mass of loosely aggregated connective tissue (collagen fibrils and mucopolysaccharides, often with some fibroblast cells) on the inner wall of the artery. The process may be initiated by a small lesion in the wall. Cholesterol and other lipids then begin to accumulate in the plaque, with a small amount of calcium. Later, as the plaque grows, it incorporates more calcium and becomes harder. By diminishing the size of the lumen of the artery it leads to decrease in the flow of blood to the tissues, to increase in blood pressure, and to damage to the heart and other organs because of the restricted supply of oxygen.
The main way in which EDTA operates to improve the cardiovascular system may be by removing calcium ions from the plaques. The cholesterol could then more easily be removed by the high-density lipoprotein. Other ways in which EDTA chelation might be beneficial have been discussed by Dr. Bruce W. Halstead in his 1979 book The Scientific Basis of EDTA Chelation Therapy. Halstead discusses the toxicity of EDTA at length. When the amount and the rate of administration are controlled in the recommended manner, the substance shows few side effects. Decrease in calcium concentration is corrected by administration of calcium compounds. Halstead says that during the thirty years before 1979 more than 150,000 patients in the United States received more than two million treat ments by EDTA chelation therapy, mainly for cardiovascular disease, and that when it is properly administered it can be used with safety. Both he and Walker (1980) recommend that it be administered only by a physician thoroughly trained in EDTA chelation therapy. Chelation therapy is far safer and much cheaper than having a by-pass operation. There seems to be a reasonable chance that this treatment would obviate the need for the operation. When I testified in 1984 at the hearing of an orthomolecular physician, the assistant attorney general of the State of California, who was the pros ecutor, asked me if I knew that EDTA chelation therapy for controlling cardiovascular problems had not been approved by the Food and Drug Administration. My answer was “Yes, I know that. I also know that the same EDTA therapy is approved by the FDA for heavy-metal detoxifica tion, and that the reason it does not have FDA approval for cardiovascular problems is that no one has tried to get it. Many years ago Abbott Labora tories, which owned the U.S. patent rights, dropped its application for FDA approval for treating arteriosclerotic disease, for financial reasons— the patent would expire too soon. No one else could afford to apply.” Despite the facts that this therapy for cardiovascular disease lacks FDA approval because pharmaceutical companies are not interested in obtaining it and that there is no legal bar to its use by physicians for this purpose, there has been a good bit of harassment by the government of physicians who use this therapy (Halstead, 1979; Walker, 1980). This harassment has the support of some medical societies, and, like the similar harassment of orthomolecular physicians, it seems to be based largely on ignorance and bias.
19.C a n c e r
Cancer, including neoplasms of the lymphatic and hematopoietic (bloodcell-forming) systems, is the cause of 22 percent of all deaths in the United States. Each year about 600,000 people develop cancer, and most of them, more than 420,000, die of the disease. The amount of suffering associated with cancer is much greater than that for most other diseases. It is for this reason that the federal government has emphasized research on cancer and has allocated several hundred million dollars per year for cancer research, reaching $1 billion this year. Despite the great amount of money and effort expended in the study of cancer, progress during the last twenty-five years has been slow. A signifi cant increase in survival time after diagnosis was achieved about thirty years ago, largely through improvements in the techniques of surgery and anesthesia. During the last twenty-five years some improvement in treat ment of certain kinds of cancer has been achieved, mainly through the use of high-energy radiation and chemotherapy, but for most kinds of cancer there has been essentially no decrease in either incidence or length of time of survival after diagnosis, and it has become evident that some new ideas are needed, if greater control over this scourge is to be achieved. One new idea is that large doses of vitamin C may be used both to prevent cancer and to treat it. The most important work along this line has been carried out by Dr. Ewan Cameron, formerly chief surgeon in Vale of
Leven Hospital, Loch Lomondside, Scotland, and now medical director of the Linus Pauling Institute of Science and Medicine. I have had the good fortune of having been associated with Dr. Cameron in his clinical research in this area during the last fourteen years. Accounts of our work are given in the book Cancer and Vitamin C (1979) and the published papers cited in the references section and are summarized later in this chapter. Another surgeon who has made important contributions in this field is Dr. Fukumi Morishige, of Fukuoka, Japan. Irwin Stone in his 1972 book The Healing Factor: Vitamin C Against Disease discussed the early reports that doses of vitamin C of 1 to 4 grams (g) per day, sometimes given together with an increased intake of vitamin A, seemed to have value in controlling cancer in some patients. This work was done largely by German physicians in the period between 1940 and 1956. Despite the indication that these doses of vitamin C were of value in the treatment of cancer, the early studies did not lead to a thorough exami nation of the possible virtues of vitamin C in that connection. Some favor able results were also reported in studies with animals, but the early work in this field too was not followed up. In 1951 it was reported that patients with cancer have usually a very small concentration of vitamin C in the blood plasma and in the leucocytes of the blood, often only about half the value for other people. This observa tion has been verified many times during the last thirty years. In 1979 Cameron, Pauling, and Brian Leibovitz listed thirteen studies, all showing large decreases in both plasma and leucocyte concentrations. The level of ascorbic acid in the leucocytes of cancer patients is usually so low that the leucocytes are not able to carry out their important function of phagocyto sis, of engulfing and digesting bacteria and other foreign cells, including malignant cells, in the body. A reasonable explanation of the low level of vitamin C in the blood of cancer patients is that their bodies are using up the vitamin in an effort to control the disease. The low level suggests that they should be given a large amount of the vitamin in order to keep their bodily defenses as effective as possible. Only one of the early reports on vitamin C and cancer dealt with the use of large doses of vitamin C over as long a period as eighteen months. In 1954 Dr. Edward Greer, of Robinson, Illinois, published a report about a remarkable patient who apparently controlled his cancer (chronic myeloid leukemia) over a period of two years by the oral intake of very large amounts of vitamin C. This patient, an elderly executive of an oil company, had a number of concurrent illnesses. He developed chronic heart disease in September 1951 and was described in May 1952 as having alcoholic cirrho sis of the liver and polycythemia (an increased number of circulating red blood cells). In August 1952 the diagnosis of chronic myeloid leukemia was established and verified by an independent hematologist. In September
1952, after extraction of some of his teeth, he was advised to take some vitamin G to promote healing of his gums. He immediately began to take very large amounts, from 24.5 g to 42 g per day (seven 500-milligram (mg) tablets taken seven to twelve times a day). He said that he set this regime for himself because he felt so much better when he took these very large doses. The patient repeatedly remarked about his feeling of well-being, and he continued in active employment. On two occasions Greer insisted that the vitamin C be stopped. Both times when the patient did so his spleen and liver became enlarged, soft, and tender, his temperature rose to 101 degrees, and he complained of general malaise and fatigue, typical leukemic symp toms. His signs and symptoms rapidly improved when he resumed the intake of vitamin C. He died of acute cardiac decompensation in March 1954, at age seventy-three. His spleen was then firm, and the leukemia, polycythmia, cirrhosis, and myocarditis had shown no progression during the eighteen months since he began his intake of large doses of vitamin C. Greer concluded that “the intake of the huge dose of ascorbic acid appeared to be essential for the welfare of the patient.” In 1968 Cheraskin and his associates described a synergistic effect of supplemental ascorbate on the radiation response in patients with squamous-cell carcinomas of the uterine cervix. Twenty-seven patients were given 750 mg of ascorbic acid per day, beginning one week before the radiation treatment and continuing until three weeks after its termination; in addition they received a vitamin-mineral supplement and general nutri tional advice (decrease in intake of sucrose). The controls were twentyseven similar patients who did not receive the vitamins or nutritional advice. Radiation therapy was equally vigorous for the two groups. The response to the radiation was significantly higher for the nutritionally treated patients (average score 97.5) than for the controls (average score 63.3). Thus there is some evidence that cancer patients undergoing radio therapy have an increased requirement for ascorbic acid and that satisfying this increased requirement protects against some of the harmful effects of irradiation as well as potentiating the therapeutic response. The late Dr. William McCormick of Toronto appears to have been the first to recognize that the generalized connective-tissue changes that attend scurvy are identical with the local connective-tissue changes observed in the immediate vicinity of invading neoplastic cells (McCormick, 1959). He surmised that the nutrient (vitamin C) known to be capable of preventing such generalized changes in scurvy might have similar effects in cancer. The evidence that cancer patients are almost invariably depleted of ascor bate lent support to his view. There are some other interesting associations between scurvy and cancer. The historical literature contains many allusions to the increased frequency of “cancers and tumors” in scurvy victims. A typical autopsy report of
James Lind (Lind, 1753) contains phrases such as “all parts were so mixed up and blended together to form one mass or lump that individual organs could not be identified,” surely an eighteenth-century morbid anatomist’s graphic description of neoplastic infiltration. Conversely, in advanced hu man cancer, the premortal features of anemia, cachexia, extreme lassitude, hemorrhages, ulceration, susceptibility to infections, and abnormally low tissue, plasma, and leucocyte ascorbate levels, with terminal adrenal fail ure, are virtually identical with the premortal features of advanced human scurvy. Epidemiological evidence indicates that cancer incidence in large popula tion groups is inversely related to average daily ascorbate intake. Of the several different published investigations, all giving essentially the same result, I mention the work of the Norwegian investigator Bjelke who in 1973 and 1974 published accounts of the exhaustive studies that he had made of gastrointestinal cancers by means of a dietary survey by mail and a case-controlled study. His work, which involved more than thirty thousand people in the United States and Norway, included a determination of the consumption of various foods, as well as smoking habits and other factors. He found a negative correlation between the consumption of fruits, berries, vegetables, and vitamin G and the incidence of gastric cancer, whereas starchy foods, coffee, and salted fish were positively correlated. The two most important factors were, he concluded, the total intake of vegetables and the intake of vitamin C. The greater the intake of vegetables and of vitamin C, the smaller is the incidence of cancer. In 1973 I went to the National Cancer Institute to show a dozen top specialists there the case histories of the first forty patients with advanced cancer in Vale of Leven Hospital, Loch Lomondside, Scotland, who had been treated with 10 g of vitamin C per day by Dr. Ewan Cameron; my objective was to ask these specialists to carry out a controlled trial of vita min C. They were not impressed by the evidence or the possibility that some control over cancer could be achieved by using large doses of this vitamin as an adjunct to appropriate conventional therapy. My wife, who had accompanied me, said afterwards that she had never before seen a group of medical researchers with less interest in new ideas. They told me that the National Cancer Institute would not do anything with vitamin C until studies had been made with animals. Those specialists did suggest, however, that I apply to the National Can cer Institute for a grant to provide support for our Institute in California to carry out such a study. I at once applied to the institute for a grant to support studies of vitamin C in relation to cancer in mice and guinea pigs. It was approved as scientifically sound by the institute’s consultants, but it was turned down. My next seven applications met the same fate. Finally the National Cancer Institute made a grant to us that provided partial
support for a careful study of vitamin C in relation to spontaneous breast cancer in mice that we conducted in our institute in Palo Alto from 1981 to 1984. This study is by far the most carefully carried out and reliable ani mal study of vitamin C and cancer that has ever been made (Pauling et al., 1985). The mice used in this investigation, strain RIII, begin to develop palpa ble breast tumors at about age forty weeks. Formation of the tumors in volves a virus that is transmitted from mother to daughter in the maternal milk. The rate at which the first tumor develops after the end of the lag period is constant—that is, after that age the tumorless mice have the same chance each week of demonstrating the first tumor. In our study we had seven groups of mice, fifty in each group, eating carefully prepared food containing percentages of 0.076, 1.86, 2.9, 4.2, 8.0, 8.1, or 8.3 of added ascorbic acid. They began these diets at age 9 weeks and continued it to age 114 weeks. Mice burdened with tumors were killed to prevent suffering. We found that the lag period increased steadily with increasing intake of vitamin C, from age 38 weeks for 0.076 percent C to age 52 weeks for 8.3 percent C. Also, the rate of appearance of the first tumor among each group of mice decreased steadily in percentage, from 2.7 per week for 0.075 percent C to 0.7 per week for 8.3 percent C. The biostatistical evaluation of the results shows that the confidence level of the conclusion that increased amounts of vitamin C in their food leads to de creased incidence of spontaneous breast cancer in this strain of mice is extremely high. The chance that the observations are the results of a statis tical fluctuation is only about one in a million. The overall result is that the age at which the tumor appears increases greatly with increased intake of vitamin C. This age for half the mice to develop a tumor (the median age) increases from 66 weeks for the smallest amount of the vitamin to 120 weeks for the largest amount. Development of the cancer is delayed in the RIII mouse strain from middle age to extreme old age. Similar results with skin cancer in mice caused by irradiation with longwavelength ultraviolet light (similar to sunlight) were obtained in an ear lier study in our institute (supported by contributions by many people, not by the National Cancer Institute) (Pauling, Willoughby, et al., 1980). Other animal studies made by various investigators, usually with much smaller groups, have given less reliable results. It has been recognized for many years that patients with cancer have a decreased level of vitamin C in the blood and also that these patients, especially children with cancer, have a high tendency to develop infections. Infection is a major cause of morbidity and of mortality in children with cancer, partially because the anticancer therapy damages the immune mechanism.
The low level of vitamin G in the blood should, of course, be rectified for all cancer patients by a high intake of the vitamin. This high intake should function to provide some protection against infectious diseases and should be a valuable adjunct to conventional therapy in the treatment of the infec tious diseases as well as of the cancer itself. These facts about vitamin G, infection, and cancer seem never to have been learned or to have been forgotten by many physicians. An example is a recent article on infections in children with cancer (Hughes, W. T., 1984, “Infections in children with cancer: Part I: Most common causes and how to treat them,” in Primary Care & Cancer, October, pp. 66-72). This article mentions eleven factors as indicators of increased susceptibility of infectious disease in a child with malignancy. One of these factors is malnutrition. There is some discussion of the effect of the anticancer therapy and the type and extent of the malig nancy on the natural defense mechanisms of the body, but there is no discussion of vitamin C and other nutrients in strengthening the defense mechanisms and essentially no discussion or recommendations about nutri tion. There is no mention in the article of the fact that cancer patients have a decreased level of ascorbate in the blood, which should be rectified. Ascorbate in the human body has rather wide powers to destroy toxic substances. It collaborates with enzymes in the liver to react with these substances, often by hydroxylating them, converting them into other sub stances that are not toxic, for elimination then in the urine. We do not yet have information about the extent to which the optimum intake of vitamin C can provide protection against the carcinogenic substances in our foods, drinks, and environment that get into our bodies, but some examples show that this effect may be large. Nitrites and nitrates in foods such as bacon and other preserved meats react in the stomach with amino compounds in the stomach contents to form nitrosamines, which are carcinogenic and which cause cancer of the stomach. A good intake of vitamin C destroys the nitrites and nitrates and prevents stomach cancer. A vigorous effort is being made now to reduce the amounts of nitrites and nitrates in foods, as a way of controlling cancer. Increased intake of vitamin C can also help to achieve this end. It has also been reported that the cancers that often appear in the blad ders of cigar smokers and other users of tobacco regress if the patient ingests a sufficient amount of ascorbic acid, 1 g per day or more. Schlegel, Pipkin, Nishimura, and Schultz (1980) found the ascorbic-acid level of the urine to be about half as great for smokers as for nonsmokers and to be low for patients with bladder tumors. They also found with mice that implanta tion in the bladder of a pellet containing 3-hydroxyanthranilic acid (a de rivative of the amino acid tryptophan) caused bladder tumors to develop if the mice were receiving a normal diet but not if they had extra ascorbic acid in their drinking water. The authors suggest that the ascorbic acid prevents
the oxidation of 3-hydroxyanthranilic acid to a carcinogenic oxidation product. They state, “There seems to be reason to consider the beneficial effects of an adequate ascorbic acid level in the urine (corresponding to a rate of intake of 1.5 g per day) as a possible preventive measure in regard to bladder tumor formation and recurrence.” They also call attention to inves tigations indicating that ascorbic acid may have a beneficial effect on the aging process of atherosclerosis, the hardening and thickening of the walls of the arteries (Willis and Fishman, 1955; Sokoloff and others, 1966). It was reported by Dr. Robert Bruce, director of the Toronto branch of the Ludwig Cancer Research Institute, in 1977 that there are mutagenic and presumably carcinogenic substances in the intestinal contents of human beings. Later he and his associates reported that a good intake of vitamin C greatly reduces the amount of these substances (Bruce 1979). In this way, and also be reducing the residence time of the waste material in the body, as was discussed in Chapter 10, a proper intake of vitamin C helps to protect the lower bowel against cancer Colonic polyposis is a genetic disease characterized by the formation of large numbers of polyps in the colon and rectum. These polyps are benign tumors, but their presence has long been recognized as a premalignant condition. According to Willis (1973), “Victims of familial polyposis are almost certain to die of carcinoma of the colon or rectum at an early age.” There is, however, now hope for them. Studies by DeCosse et al. (1975), Lai et al. (1977), and Watne et al. (1977) with sixteen persons with famil ial polyposis gave the result that the regular intake of 3 grams of vitamin C per day caused the polyps to disappear in half of the patients. There is a real possibility that a larger intake, of 10 or 20 g per day, would control the disease in others. Before we met each other and began our collaboration, Ewan Cameron had carried out operations on hundreds of patients with cancer in his sur gery in Scotland. Like many other people, he thought that this disease, which causes so much suffering, needed a fresh approach. He gathered a large amount of information about cancer and formulated a new theory on its causation, which he published in a book, Hyaluronidase and Cancer, in 1966. In this book he suggested that a significant amount of control over cancer might be achieved by strengthening the natural defense mechanisms of the human body. In particular, he mentioned that malignant tumors are known to produce an enzyme, hyaluronidase, that attacks the intercellular cement of surrounding tissues, weakening this cement to such an extent as to permit invasion of the tissues by the neoplasm. He suggested that some way might be found to strengthen the intercellular cement and in this way to build up the natural defense mechanisms of the body to such an extent as to resist attack by the malignant cells. For several years he tried giving various hormones and other substances to patients with advanced cancer in
the hope of achieving this result, but he did not succeed in finding any substance or mixture of substances that was effective. I read his book and was much impressed by his argument. I had been working on vitamin C in relation to the common cold and other diseases, and in 1971 I had the idea that the known property of ascorbic acid of increasing the rate of synthesis of collagen would permit large doses of vitamin C to strengthen the intercellular cement by the increased synthesis of collagen fibrils, which are an important part of this intercellular cement. I mentioned this idea in an address that I gave at the dedication of the Ben May Laboratory for Cancer Research in Pritzker Medical School, Univer sity of Chicago. By then, Cameron had independently reached the tentative conclusion that ascorbate might be involved in the synthesis of the naturally occurring hyaluronidase inhibitor and had already begun cautiously to pre scribe ascorbate to dying cancer patients under his care. In November 1971 he read an account of my address in the New York Times. We immediately corresponded, and this marked the beginning of a long and productive association. Whereas Cameron had been disappointed in his trials of various hor mones, he immediately thought that the treatment with vitamin C was of considerable benefit to the patients, and during the next ten years he gave the vitamin in large doses to several hundred patients with advanced can cer, almost all of them being patients for whom the conventional methods of treatment had been tried and found to be of no further benefit. He and his coworkers published several papers on their observations. In one paper they reported that the vitamin C seemed to control pain quite effectively, so that patients who had been receiving large doses of morphine or diamorphine could stop taking the narcotic drug (Cameron and Baird, 1973). He also published a detailed report on the first fifty patients with advanced cancer to be treated with large doses of vitamin C (Cameron and Campbell, 1974), and a paper on one patient who seemed to recover com pletely from cancer when treated with vitamin C, in whom, however, the cancer returned when the intake of vitamin C was stopped, and who again recovered completely when the treatment with vitamin C was resumed. This patient continues to take vitamin C, 12.5 g per day, and after twelve years seems to be in excellent health (Cameron, Campbell, and Jack, 1975). The first observation made by Cameron was that most of the ascorbatetreated patients entered upon a period of increased well-being and general clinical improvement. The benefits enjoyed by a majority of these patients included, in addition to increased well-being, relief from pain, a decrease in malignant ascites (cells shed from the tumors, potentially initiators of new tumors and so the agents of metastasis) and malignant pleural effusions, relief from hematuria, some reversal of malignant hepatomegaly and malig-
nant jaundice, and decrease in the red-cell sedimentation rate and in the serum seromucoid level, all accepted indicators of lessening malignant ac tivity. It was thus possible to conclude that both the increase in well-being and the apparent increase in survival time resulted from a significant attack by the ascorbate, either directly or by way of the natural protective mecha nisms of the body, on the malignancy itself. By 1973 it seemed to Cameron and me that a controlled trial should be carried out, in which half of the patients, selected by tossing a coin or by some more sophisticated randomizing process, received 10 g of vitamin C each day and the others received a placebo. By that time, however, Cameron had become so convinced of the value of vitamin C to patients with advanced cancer that he was unwilling for ethical reasons to withhold it from any patient to whom he had the power to give it; accordingly he could not carry out such a trial with his patients. I then went to the Na tional Cancer Institute to suggest that it carry out such a trial, as mentioned earlier in this chapter. Even though we could not carry out a double-blind randomized clinical trial, we could carry out a controlled trial. The Vale of Leven Hospital is a large one, with 440 beds, and it registers about 500 new cancer patients each year. Although Cameron was the senior consultant surgeon in admin istrative charge of the 100 surgical beds, he was in direct medical charge of only some of these cancer patients. At first none of the other physicians or surgeons gave large doses of vitamin C to their patients, and even in later years many of the Vale of Leven cancer patients have not received this treatment. Thus there have been other cancer patients closely similar to the ascorbate-treated patients, receiving the same treatment, except for the as corbate, from the same medical and surgical staff, in the same hospital. These patients could serve as the controls. In 1976 we reported the survival times of one hundred terminal cancer patients given supplemental ascorbate and those of a control group of one thousand patients of similar initial status who had been treated by the same clinicians in the same hospital and who had been managed identically ex cept for the supplemental ascorbate. The one thousand controls thus pro vided ten control patients for each ascorbate-treated patient, matched as to sex, age, primary tumor type, and clinical status of “untreatability.” We employed an outside doctor, who had no knowledge of the survival times of the ascorbate-treated patients, to examine the case histories of each of the control patients and to record for each of them the survival time—the time in days between the date of abandonment of all conventional forms of treatment and the date of death. The results were surprising, even to us (see illustration on page 172) (Cameron and Pauling, 1978). On 10 August 1976 all of the one thousand control patients had died, whereas eighteen of the one hundred ascorbate-
treated patients were still living. On that date the average time of survival after the date of “untreatability” was 4.2 times as great for the ascorbatetreated patients as for their matched controls. The one hundred ascorbatetreated patients have lived on the average more than three hundred days longer than their matched controls, and in addition it is our strong clinical impression that they have lived happier lives during this terminal period. Moreover, a few of them continue to survive, still taking their daily doses of sodium ascorbate, and some of them might well be considered to have been “cured” of their malignant disease, in that they are free of overt manifesta tions of cancer and are leading normal lives. We considered this to be a remarkable achievement, bearing in mind that if the mortality of cancer could be decreased by 5 percent the lives of twenty thousand American cancer patients would be saved each year. Because of the importance of the problem of cancer, we made a second examination of the case histories of the Vale of Leven patients in 1978,
again with one hundred ascorbate-treated patients and one thousand matched controls (Cameron and Pauling, 1978). Ten of the original one hundred ascorbate-treated patients, mainly with rare forms of cancer for whom it had been difficult to find sets of exactly matched controls, were replaced by new ones, and the one thousand matched controls were inde pendently selected, without regard as to whether or not they had been selected before (about half of them were in the earlier set). Some of the results of this study are given in the illustrations on pages 174 and 175. The one hundred ascorbate-treated patients and their matched controls (same type of primary tumor, same sex, and same age to within five years) were divided into nine groups, based on the type of primary tumor; for example, 17 ascorbate-treated patients and 170 controls with cancer of the colon. (The ninth group included patients with types of cancer other than those shown in the illustrations not cited.) Survival times were measured from the date when the patient was determined to be “untreatable”; that is, when the conventional therapies were deemed to be no longer effective—at this date or a few days later ascorbate treatment was begun. In 1978 the mean survival times for the nine groups were between 114 and 435 days greater for the vitamin-C groups than for the corresponding control groups, an average of 255 days for all groups, and were continuing to increase because 8 percent of the vitamin-C patients were still alive, and none of the controls were. A similar study was carried out in the Fukuoka Torikai Hospital in Japan during the five years beginning 1 January 1973 (Morishige and Murata, 1979), with results, shown in the illustration on page 176, similar to those obtained in Vale of Leven Hospital. More recently, two controlled trials have been carried out in the Mayo Clinic. This Mayo work has been publicized as refuting the Vale of Leven and Fukuoka Torikai studies. The record shows, however, that the Mayo Clinic doctors did not follow the protocols of those studies. That work has, therefore, only small relevance to the question of how great the value of vitamin C is for cancer patients. The first Mayo Clinic study (Creagen et al., 1979), showed only a small protective effect of vitamin C. Cameron and I attributed this reported result to the fact that most of the Mayo Clinic patients had already received heavy doses of cytotoxic drugs, which damage the immune system and interfere with the action of vitamin C, and the fact that the controls were also taking vitamin C in much larger amounts than were the controls in Scotland or Japan. Only 4 percent of the Vale of Leven patients had received prior chemotherapy. In our studies the vitamin-C patients took large amounts of the vitamin, without stopping, for the rest of their lives or until the present time, some for as much as fourteen years. In the second Mayo Clinic Study (Moertel et
Vale of Leven survival times For cancers with eight different primary sites in the Vale
of Leven study (summarized in Figure 19.1) the survival times of the vitamin-C-treated patients are compared to those of their matched controls. Survival is measured from the day
al., 1985), the vitamin-C patients received the vitamin for only a short time (median 2.5 months). None of the vitamin-C patients died while taking the vitamin (amount somewhat less than 10 g per day). They were, however, studied for another two years, during which their survival record was no better than that of the controls, or even somewhat worse. The Moertel paper and a spokesman for the National Cancer Institute, who commented on it (Wittes, 1985) both suppressed the fact that the vitamin-C patients were not receiving vitamin C when they died and had not received any for a long time (median 10.5 months). They announced vigorously that this study showed finally and definitely that vitamin C has no value against advanced cancer and recommended that no more studies of vitamin C be made.
Their results provided no basis whatever for this conclusion, because in fact their patients died only after being deprived of the vitamin C. To the extent that their study showed anything, it is that cancer patients should not stop taking their large doses of vitamin C. Yet the study was heralded upon publication as one that reflected adversely on the Cameron-Pauling work. When this Mayo Clinic paper appeared, 17 January 1985, Cameron and I were angry that Moertel and his Mayo Clinic associates, the spokes man for the National Cancer Institute, and also the editor of the New England Journal of Medicine had managed to prevent us from obtaining any information about their results until a few hours before their publica tion. Six weeks earlier Moertel refused to tell me anything about the work,
except that their paper was going to be published. In a letter to me he promised that he would arrange for me to have a copy of the paper several days before publication, but he broke that promise. The misrepresentation by Moertel and his associates and by the Na tional Cancer Institute spokesman has done great harm. Cancer patients have informed us that they are stopping their vitamin C because of the “negative results” reported by the Mayo Clinic. It is not often that unethical behavior of scientists is reported. Fraud committed by young physicians doing medical research has been turned up several times in the last few years. Improper representation of the re sults of clinical studies, as in the second Mayo Clinic report, is especially to be condemned because of its effect in increasing the amount of human suffering. The Mayo Clinic paper stimulated a vigorous response from the public addressed to Cameron and me. The first two letters reached me five days after the publication of the paper. The following excerpts are quoted with permission of the writers. One letter was written to Moertel, the principal Mayo Clinic investiga tor, by a man in Utah, who sent a copy to me. It was written the day after publication, and the entire letter reads as follows: Dear Dr. Moertel: In March 1983 my right lung was removed due to cancer. The X-ray showed no spread and no follow-up treatment was given.
On May 8, 1984 a cat-scan showed metastasis to the brain, two small tumors on front of brain, right side and left side, 3 cm. Also one large tumor at the back, 6 cm. The prognosis was terminal with about a year to live. The treatment was radiation at LDS Hospital, Salt Lake City which would shrink and control the tumors for a while, but not eradicate them. I immediately went on a nutritional program which included Vitamin C. 1 went to my bowel tolerance level of 36 grams a day. On July 9th another cat-scan was done at LDS Hospital and the tumors were completely gone. I just finished a follow-up cat-scan and chest X-ray which showed no sign of cancer. I feel strongly that the Vitamin C (and other nutrients) together with the radiation removed the tumors. I am still on 36 grams daily and plan to be indefinitely and feel the Vitamin C has played an important part of my miraculous cure. In the book “Cancer and Vitamin C” by Ewan Cameron and Linus Pauling, they do not suggest the use of vitamin C alone to cure cancer but only to augment traditional treatments. My records are open for verification. I realize you do not like case histories, but X-rays and doctors reports plus real results are pretty good proof. I do not know how much Vitamin C you gave in your blind studies, but each person’s requirements are different. Therefore, any amount short of bowel tolerance levels, which could not be done in a blind study such as yours, is useless. It is my hope that if you are truly interested in the cancer patient you will reconsider your position. The second letter was written to me by an eighty-one-year-old man in San Francisco. Here are some excerpts from his letter: This letter is essentially about the use of your basic theories concerning cancer and vitamin C. As I wrote before, I had surgery for colorectal cancer on 4 September, 1980. It had metastasized to the liver where a tumor about 35 mm in diameter was found. It was not operable under the circumstances. I started reading on the subject and taking injections of 5-FU at the same time. I knew you had written on vitamin C and the common cold but was unaware of your work with Dr. Cameron on cancer in Scotland. In the literature, I quickly found that metastasized cancer to the liver was tantamount to a death sentence, survival rates ranging from a few weeks to 18 months. In most studies, untreated metastases had a
survival period averaging 6.1 months. I also quickly became convinced that the fluorinated pyrimidine 5-FU was nothing more than a placebo. I decided to quit taking it. The oncologist I was seeing did not object and ordered a liver scan. This showed that the tumor had grown from 35 mm to 52 millimeters in diameter while I was taking the injections. By nature, I am a sanguine man and since fifteen, I have known that life would be the death of me yet. Gathering all my material together and using your thinking on the subject as a guide, I worked out a regime based on vitamin G, vitamin E and other dietary supplements. The second liver scan, after I ingested 10-12 grams of vitamin G daily for three months, showed no change in the size or texture of the liver lesion. It was there, all right, but it had not grown. I continued my self-treatment, looked for a medical doctor who could help me. I found myself faced with an ocean of ignorance on the part of the medical fraternity as to the immensely complex process by which the human body absorbs and uses the materials upon which it exists. And profound indifference as to what I was doing. I know 12 doctors personally, most of them I consider friends. Five of them tell me that they had one course in nutrition for a single semester in medical school. The other seven had no course at all. None asked me anything about what I was doing. I continued the liver scans, one each three months. The lesion remained the same until the ultrasound scan of 15 October, 1984. To my surprise, this scan showed a decrease amounting to 32% in the cubic content of the tumor. Because of the nature of the finding, the series was run twice. Once by the technician and then by the doctor in charge of the laboratory to make sure of an accurate finding. The tumor had also begun to be infiltrated with calcium. During all of this time, I have been reasonably healthy with no sign of cancer, working at one thing or another and sailing our boat on the Bay. I have a chest x-ray each year because the normal path of the decrease is from the liver to the lungs. My lungs are clear. In your writing, you suggest that the intake of ascorbic acid be moved up until one becomes uncomfortable and then to back down a bit. In your letter to me, you proposed 25 grams of G daily. I have been taking 36 grams daily for more than two years now. In divided portions, I have no difficulty with this. I have planned on writing you for more than a year, but pure sloth has caused me to put it off. The present spur to my intent is the article read at breakfast two days ago about the Mayo Clinic procedure. I think that this is a shabby business indeed. Mayo is the last place I
would want to see used for a study of vitamin C under any conditions. They are flawed because of the manner in which they did their first so-called study. What is needed should be obvious to a blind man. That is, nothing short of a series of massive tests, using thousands of patients with scores of different kinds of cancer. And these grouped in various stages of this degenerative disease. It would have to be a national effort as no clinic, hospital or teaching university could possibly carry it out on the necessary scale. I am sure that you are absolutely right in saying that vitamin C, while not a cure for cancer, is a vital and potent adjunct in the management and control of the disease. And it is a fact that any form of chemotherapy will damage the body’s own immune system. In my case, I must have achieved a dandy immune system or my cancer would long ago have reached one of the lymph glands. That the tumor on my liver has become non-invasive is obvious. That it will stay that way is not obvious. Knowing that it is there puts me in the position of living under the sword of Damocles. I am reasonably certain that I shall die of cancer. . . if I do not die of old age first. I was 81 years of age on January 16, 1985. These letters are representative of scores of letters that Cameron and I have received. Such evidence may be dismissed as anecdotal when com pared to the statistical evidence from large-scale trials—with inadequate intakes of vitamin C. The anecdotes nonetheless should challenge conscien tious investigators to run large-scale trials with intakes of vitamin C as prescribed by Cameron. In Chapter 26 I have more to say about the behavior of Moertel and his colleagues in illustration of the difference between vitamins and drugs. Based upon the results of our studies, Cameron and I have recommended that a high intake of vitamin C be taken by every cancer patient, as an adjunct to appropriate conventional therapy and beginning as early in the course of the disease as possible. How many people could be helped in this way? The quantitative infor mation that we have is based mainly on the observation of patients with advanced cancer in Scotland who received 10 g of vitamin C per day. As the result of observations on several hundred patients, Cameron reached the following conclusions about the effects of administering this amount of vitamin C to patients with advanced cancer:
Better results are obtained with intakes greater than 10 g per day. In our book Cancer and Vitamin C, Cameron and I stated our conclusion that “This simple and safe treatment, the ingestion of large amounts of vitamin C, is of definite value in the treatment of patients with advanced cancer. Although the evidence is as yet not so strong, we believe that vita min C has even greater value for the treatment of cancer patients with the disease in earlier stages and also for the prevention of cancer.” The last sentences in that book are the following: With the possible exception of during intense chemotherapy, we strongly advocate the use of supplemental ascorbate in the management of all cancer patients from as early in the illness as possible. We believe that this simple measure would improve the overall results of cancer treatment quite dramatically, not only by making the patients more resistant to their illness but also by protecting them against some of the serious and occasionally fatal complications of the cancer treatment itself. We are quite convinced that in the not too distant future supplemental ascorbate will have an established place in all cancer-treatment regimes. We have now had the opportunity to observe patients who have taken 10 g or more per day of vitamin C during intense chemotherapy. It seems clear that there is benefit from the vitamin G, which controls to a consider able extent the disagreeable side effects of the cytotoxic chemotherapeutic agents, such as nausea and loss of hair, and that benefit seems to add its value to that of the chemotherapeutic agent. We now recommend a high intake of vitamin C, in some cases up to the bowel-tolerance limit (Chapter 14), beginning as early as possible. There are many advantages to using vitamin G as an adjunct to appro priate conventional therapy in the treatment of cancer patients. Vitamin C is inexpensive. It has no serious side effects, but instead improves the appe tite, controls the feeling of misery that plagues cancer patients, improves the general health, and gives the patient a greater capacity to enjoy life. For every patient there is the chance that through its use, together with the appropriate conventional therapy and good intakes of other nutrients, the disease can be kept under control for many years.
20.T h e
B r a in
Of all of the organs in the human body, the brain is the most sensitive to its molecular composition. The proper functioning of the brain is known to require the presence of many different kinds of molecules in the right concentrations. This is the physical, the molecular environment of the mind. The physiology of the brain tends always to maintain that environ ment constant. In persons suffering from scurvy the concentration of vita min C in the brain is kept high even when there is almost complete deple tion in the blood and other tissues. So sensitive is the brain that if a person is deprived of oxygen for a few minutes, the brain dies (as is shown by a flat electroencephalic curve), while the other organs survive. In considering the health of the rest of the body, we have encountered the biochemical individuality that sets each person singularly apart from every other (Chapter 10). Can it be argued that they do not differ in the amounts of critical substances supplied to the brain? We must ask then what part the molecular environment of each mind plays in establishing the singular ity of each individual’s personality. This simple question leads us to the possibility that the brain may suffer a localized cerebral avitaminosis or other localized cerebral deficiency dis ease. There is the possibility that some human beings have a sort of cere bral scurvy, without any of the other manifestations, or a sort of cerebral
pellagra, or cerebral pernicious anemia. It was pointed out by Zuckerkandl and Pauling (1962) that every vitamin, every essential amino acid, and every other essential nutrilite represents a molecular disease, which our distant ancestors learned to control, when it began to afflict them, by select ing a therapeutic diet, and which has continued to be kept under control in this way. The localized deficiency diseases mentioned above may be com pound molecular diseases, involving not only the original lesion, the loss of the ability to synthesize the vital substance, but also another lesion, one that causes a decreased rate of transfer across a membrane, such as the bloodbrain barrier, to the affected organ, or an increased rate of destruction of the vital substance in the organ, or some other perturbing reaction. These deficiencies in the supply of synthesis of crucial molecules may manifest themselves in symptoms diagnosed as psychosis of one kind or another to be treated by attempts to modify the patient’s behavior or personality. In the ninth edition of the Encyclopaedia Britannica (1881) insanity is defined as a chronic disease of the brain inducing chronic disordered mental symptoms. The author of the article, J. Batty Tuke, M.D., lecturer on insanity, School of Medicine, Edinburgh, then stated that this definition possesses the great practical advantage of keeping before the student the primary fact that insanity is the result of disease of the brain, that it is not a mere immaterial disorder of the intellect. In the earliest epochs of medicine the corporeal character of insanity was generally admitted, and it was not until the superstitious ignorance of the Middle Ages had obliterated the scientific—though by no means always accurate—deductions of the early writers that any theory of its purely psychical character arose. At the present day it is unnecessary to combat such a theory, as it is universally accepted that the brain is the organ through which mental phenomena are manifested, and therefore it is impossible to conceive of the existence of an insane mind in a healthy brain. By 1929, when the fourteenth edition of the Encyclopaedia Britannica was published, the situation had changed, largely because of the develop ment of psychoanalysis by Sigmund Freud. The earlier definition of insan ity was deleted and was replaced by discussions from two points of view: that of the materialistic school, who held that structural changes in the brain are involved, and that of the psychogenic school, who held that insan ity is the result of abnormalities of the ego and that the structural changes in the brain observed in certain forms of insanity are caused by a perverted mentality.
Even now, half a century later, when we have extensive knowledge of the action of psychotropic drugs, brain tumors, brain injuries, slow viruses, protein starvation, and other factors affecting the function of the brain, there are still practitioners of psychoanalysis who ignore the brain and attempt only to treat the ego. When the use of vitamin B3 was introduced (by drinking milk, 1920 on, or eating bread made from flour fortified with the vitamin, 1940), it cured thousands of pellagra patients of their psychoses, as well as of the physical manifestations of their disease. For this purpose only small doses are re quired; the Recommended Daily Allowance (RDA) of the National Re search Council is 17 milligrams (mg) per day (for a 70-kilogram [kg], 154-pound, male). In 1939 Cleckley, Sydenstricker, and Geeslin reported the successful treatment of nineteen patients, and in 1941 Sydenstricker and Cleckley reported similarly successful treatment of twenty-nine pa tients, with severe psychiatric symptoms by use of moderately large doses of nicotinic acid (0.3 to 1.5 grams [g] per day). None of these patients had physical symptoms of pellagra or any other avitaminosis. More recently many other investigators have reported on the use of nicotinic acid and nicotinamide for the treatment of mental disease. Outstanding among them are Dr. Abram Hoffer and Dr. Humphry Osmond, who since 1952 have advocated and used nicotinic acid in large doses, in addition to the conven tional therapy, for the treatment of schizophrenia. Their work, which ig nited my interest in vitamins, will be discussed more fully later in this chapter. A deficiency of vitamin B12, cobalamin, whatever its cause (pernicious anemia, a genetic lack of the factor in gastric juice that is needed to trans port the vitamin into the blood; or infestation with the fish tapeworm Diphyllobothrium, whose high requirement for the vitamin results in depriva tion for the host; or excessive bacterial flora with a high requirement for the vitamin) leads to mental illness, often more pronounced than the physical consequences. The mental illness associated with pernicious anemia often appears years before the anemia develops. All of these manifestations of severe B12 deficiency are, of course, controlled by the administration of the vitamin in adequate amounts. There is also epidemiological evidence that even only moderate defi ciency of B12 may lead to mental illness. Edwin, Holten, Norum, Schrumpf, and Skaug (1965) determined the amount of B12 in the serum of every patient over thirty years old admitted to a mental hospital in Norway during a period of one year. Of the 396 patients, 5.8 percent (23) had a pathologically low concentration, less than 101 picograms per milliliter (ml), and the concentration in 9.6 percent (38) was subnormal (101 to 150
picograms per milliliter). The normal concentration is 150 to 1300 p ro grams per milliliter. The incidence of pathologically low and subnormal levels of B12 in the serums of these patients, 15.4 percent, is about thirty times that in the general population, about 0.5 percent (estimated from the reported frequency of pernicious anemia in the area, 9.3 per 100,000 per sons per year). Other investigators have also reported a higher incidence of low B12 concentrations in the serums of mental patients than in the popula tion as a whole and have suggested that B12 deficiency, whatever its origin, may lead to mental illness. These observations indicate that an increased intake of vitamin B12, as well as of other vitamins, should be a part of the treatment of every men tally ill person. The vitamin can be effectively taken by mouth, except by those persons with pernicious anemia, for whom injections are needed. An interesting investigation of the relation between intelligence, as indi cated by the results of standard mental ability tests, and the concentration of ascorbic acid in the blood plasma has been reported by Kubala and Katz (1960). The subjects were 351 students in four schools (kindergarten to college) in three cities. They were initially divided into the higher-ascorbicacid group (with more than 1.10 mg of ascorbic acid per 100 milliliters of blood plasma) and the lower-ascorbic-acid group (less than 1.10 mg per 100 milliliters) on the basis of analysis of blood samples. By matching pairs on a socioeconomic basis (family income, education of father and mother), seventy-two subjects in each group were selected. It was found that the average measured intelligence quotient (IQ) of the higher-ascorbic-acid group was greater than that of the lower-ascorbic-acid group in each of the four schools; for all seventy-two pairs of subjects the average IQ values were 113.22 and 108.71, respectively, with an average difference of 4.51. The probability that a difference this great would be found in a similar test on a uniform population is less than 5 percent; hence the observed differ ence in average IQ of the two groups is statistically significant. The subjects in both groups were then given supplementary orange juice during a period of six months, and the tests were repeated. The average measured IQ for those in the initially higher-ascorbic-acid group has in creased very little (by only 0.02), whereas that for the lower group had increased by 3.54 IQ units. This difference in increase is also statistically significant, with a probability that it is just a statistical fluctuation of less than 5 percent in a uniform population. The study was continued through a second school year with thirty-two pairs (sixty-four subjects), with similar results. The relation between the average measured IQ and the average blood-plasma ascorbic-acid concen tration for these sixty-four subjects tested four times during a period of months is shown in the illustration on page 185. These results indicate that
the IQ is raised by 3.6 units when the blood-plasma ascorbic-acid concen tration is increased by 50 percent (from 1.03 to 1.55 mg per 100 milliliters). This increase would for many people result from increasing the intake of ascorbic acid for an adult by 50 mg per day (from 100 to 150 mg per day). Kubala and Katz conclude that some of the variance in intelligence-test performance is determined by the “temporary nutritional state of the indi vidual, at least with regards to citrus or other products providing ascorbic acid.” They suggest that “alertness” or “sharpness” is diminished by a de creased intake of ascorbic acid. There is no indication in the illustration cited that maximum mental ability has been reached at the value 1.55 mg of ascorbic acid per 100 milliliters of blood plasma. This concentration corresponds for a 70-kg adult to the daily ingestion of about 180 mg of ascorbic acid. I conclude that for maximum mental performance the daily allowance of ascorbic acid should be at least three times the 60 mg recommended by the U.S. Food and Nutrition Board and at least nine times the 20 mg recommended by the corresponding British authority. Still larger intakes might have an addi tional effect. People differ from one another in their ability to fit into the world, to get along with other people, and to make their own living by contributing to the work needed to keep the world going. For many people inability is inborn, and shows up in childhood as mental retardation, slowness to learn, an impairment of the ability to think clearly. The problem of mental retar dation is a very serious one. About fifteen million people in the United
Vitamin C and IQ Relation between mean intelligence quotient and mean concentration of vitamin C in the blood plasma is shown for sixty-four school children. Four tests were made of each child over a period of eighteen months. The plasma vitamin-G concentration was changed by giving all the subjects extra orange juice during certain months. (Redrawn from Figure 1 of Kubala and Katz, 1960).
States are mentally deficient, including about two million classed as se verely deficient. The cost of taking care of the more severely retarded ones I estimate at more than $50 billion per year. Mental retardation is a cause of suffering not only to the retarded person but also to his or her family. Many causes of mental retardation are now known, and for a few it is known how to prevent or modify the genetic damage. An example is phenylketonuria (PKU), which results from the inability to make the en zyme that catalyzes the conversion of the amino acid phenylalanine into another amino acid, tyrosine. Both of these amino acids are present in the proteins in our food. A child with PKU has an excess of phenylalanine and a deficiency of tyrosine in the blood. This condition interferes with the proper development and functioning of the brain, leading to mental retar dation. If the PKU infant shortly after birth is given a special diet low in phenylalanine and is kept on the diet for several years, the severe mental retardation does not occur. Down’s syndrome (trisomy 21, mongolism) is the result of a genetic ab normality in which the cells of the person contain three, rather than two, of one of the smaller chromosomes, number 21. Persons suffering from this disease thus tend to produce 50 percent more than usual of many different kinds of enzymes, programmed by the hundreds of genes on this chromo some. As a result, such persons show many abnormalities. They are small in stature; have an abnormally large size and unusual shape of the head; abnormalities in shapes of the hands and feet; a large, protruding tongue; and the slanted eyes under epicanthal folds that caused the disease origi nally to be called mongolism. About one-third suffer from congenital heart disease, and they have an increased incidence of acute leukemia; these prob lems often result in early death. Those who survive to adulthood show ac celerated aging and usually die between forty and sixty. People with Down’s syndrome are placid and affectionate, and the in fants rarely cry. They are severely retarded mentally, with IQ usually about 50. The incidence in births to young mothers is about one in two thousand, rising to about one in twenty-two for mothers more than forty years old. Persons with Down’s syndrome constitute the largest group of institutionalized mental retardates. An important medical and scientific problem is that of finding a way of treating these genetic abnormalities, starting in infancy, that would prevent much of the mental retardation and also the physical abnormalities, such as small stature and unusual appearance. I believe that we can now see that this goal can in part be reached by nutritional and other orthomolecular measures. Even a partial decrease in the severity of mental retardation can be very important. Increase in IQ from 50 to 70 (low normal) means the
difference between a life of dependency on others and a life of independence and self-sufficiency. Dr. Ruth F. Harrell, of Old Dominion University, Norfolk, Virginia, and her collaborators Ruth Capp, Donald Davis, Julius Peerless, and Leonard Ravitz have reported the results of their double-blind study of the effect of administering a mixture of nineteen vitamins and minerals to sixteen mentally retarded children between five and fifteen years old (six boys and ten girls) (Harrell et al., 1981). Their initial IQ values, averages of measurements by three or more psychologists, varied from 17 to 70, with mean a value of 47.7. The subjects were assigned randomly to two groups. During the first four months of the double-blind study the six subjects in group 1 were given six vitamin-mineral tablets each day, and the ten sub jects in group 2 were given six placebo tablets; then for four additional months every subject received the vitamin-mineral tablets. Harrell had been inspired by having read the suggestion by Professor Roger J. Williams of the University of Texas, who in 1933 had discovered pantothenic acid, that an increased intake of important nutrients might help control some genetic diseases (Williams, 1956). She had then carried out a trial experiment with a severely retarded seven-year-old boy who was in diapers, could not speak, and had an estimated IQ of 25 to 30. A bio chemist, Dr. Mary B. Allen, devised the formulation of vitamins and min erals given in the table on page 188. On this treatment the boy soon began to talk and in a few weeks began to read and write and to act like a normal child. Two years later he was getting along well in school subjects and had an estimated IQ of 90. Allen had also administered another orthomolecular substance, thyroid, to her patients, and fourteen of the sixteen in the Harrell study also received thyroid, in amounts of 30 to 120 mg per day. The main results are shown in the illustration on page 189. The group that received the supplement for eight months showed a steady increase in average IQ, from 46 to 61. The other group showed no change during the first four months, when the placebo was given, and then an increase from 49 to 59 during the next four months, when the vitamin-mineral supple ment was given. From these results we may conclude that there is a reasonable chance that a child with severe mental retardation could by vitamin-mineral supplementation beginning early in life achieve an increase in IQ of 20 points or more. The largest individual increases reported by Harrell et al. were 24 points (42 to 66) in eight months and twenty-one points (50 to 71) in four months, enough gain to put those persons in a position to become self-sufficient. The improved nutritional status resulting from taking the vitamin-mineral supplement, with about thirty times the RDA for vitamin
Daily doses of supplementary vitamins and minerals (six tablets). Vitamin A palmitate Vitamin D (cholecalciferol) Thiamin mononitrate Riboflavin Niacinamide Calcium pantothenate Pyridoxine hydrochloride Cobalamin Folic acid Vitamin C (ascorbic acid) Vitamin E (d-a-tocopheryl succinate) Magnesium (oxide) Calcium (carbonate) Zinc (oxide) Manganese (gluconate) Copper (gluconate) Iron (ferrous fumarate) Calcium phosphate (CaHP04) Iodide (KI)
15,300 IUa 300 IU 300 mg 200 mg 750 mg 490 mg 350 mg 1000 mg 400 mg 1500 mg 600 IU 300 mg 400 mg 30 mg 3 mg 1.75 mg 7.5 mg 37.5 mg 0.15 mg
The daily dose was 6 tablets. The tablets also contained microcrystalline cellulose, povidone, stearic acid, sodium silicoaluminate, hydroxypropylmethylcellulose, propylene glycol, silica gel, polyethylene glycol, titanium dioxide, oleic acid, and tribasic sodium phosphate as excipients. The placebo tablets contained lactose, microcrystalline cellulose, stearic acid, povidone, propylene glycol, hydroxypropylmethylcellulose, titanium dioxide, and oleic acid. *Capsules with similar composition (2 capsules, GTC#2, equal 1 tablet) are available from Bronson Pharmaceuticals, La Canada, California 91011.
C and good amounts of other nutrients, would benefit anyone taking it, and it is my recommendation that this improved nutritional regimen be fol lowed by every retarded child. The cost of 180 tablets, one month’s supply, is less than $10, and is accordingly small compared with the other expenses involved in caring for a mentally retarded person. Three of the subjects in the study by Harrell et al. suffered from Down’s syndrome. Their initial IQ values were 42, 59, and 65, and the increases with intake of the vitamin-mineral supplement and thyroid (for the first two) were 24 and 11 (in eight months) and about 10 (in four months), respectively. There is no accepted conventional treatment for Down’s syndrome. The physician who has made the greatest effort to ameliorate that condition is Dr. Henry Turkel, of Detroit, Michigan. He has reported on his work in a paper communicated to the Select Committee on Nutrition and Human Needs of the United States Senate, Senator George McGovern, Chairman (Turkel, 1977), and in a book, New Hope for the Mentally Retarded— Stymied by the FDA (Turkel, 1972). In 1940 he had begun treating Down’s syndrome patients with tablets that he had developed. The tablets
contain mainly orthomolecular substances—ten vitamins, nine minerals, one amino acid (glutamic acid), choline, inositol, para-aminobenzoic acid, thyroid, unsaturated fatty acids, and digestive enzymes. These substances should improve the health of the patients. In addition his preparation con tains several drugs, given in smaller dosages than those usually prescribed. One of the drugs is pentylenetetrazole, which stimulates the central nervous system. Another is aminophylline, a heart stimulant. I do not know enough about drugs to permit me to comment on their value for these patients, but there is the possibility that their action as stimulants is beneficial. I know Dr. Turkel, and I can testify as to his sincerity and conviction. The results that he reports are striking. Many of the children show a reduction of the developmental anomalies, especially of the bones. Their appearance changes in the direction of normality. Their mental ability and behavior improve to such an extent that they are able to hold jobs and support themselves. Rapid growth (increase in height) occurs during the period when the tablets are being taken, and the growth stops during the periods when they are not taken. My conclusion is that there is little danger that this treatment or treat ment with the supplementary nutrients would do harm, and there is evi dence that the patients would receive significant benefit. There are about
300,000 people with Down’s syndrome in the United States. I think that all—especially the younger ones—should try nutritional supplementation to see to what extent it benefits them. Turkel treats Down’s syndrome patients in Michigan, but he is not allowed by the Food and Drug Administration to ship his tablets across state lines. In 1959 he filed a new-drug application with the FDA (neces sary because his tablets contain some drugs). The application was turned down, and his later efforts were also unsuccessful. The director of the National Institute of Neurological Diseases and Blindness, referring to Turkel’s treatment of Down’s syndrome patients, wrote that “On theoreti cal grounds, and based on known effects of these drugs, which consist of vitamins, minerals, and other medications, our advisors have stated that, although they are not harmful, they doubt that the drugs would be of specific value in treating mongolism.” (Turkel, 1972, p. 123.) The FDA in rejecting the new-drug application stated that “The known facts concerning mongolism preclude any reasonable hope that your products would be of benefit in this condition, which is caused by a defect in the basic cell struc ture. This finding, considered together with the long history of inability of medical science to find a treatment or cure for mongolism, suggests that this condition is beyond hope of successful treatment by the kind of preparations that you wish to recommend for this purpose.” (Turkel, 1972, p. 119.) I think that this attitude of the National Institutes of Health (NIH) and the FDA is the result of ignorance, bias, misunderstanding of the nature of vitamins and other orthomolecular substances, and lack of hope or vision— they seem to have the conviction that nothing new can be discovered. Autism is a genetic disease that manifests itself in the first one or two years of life in about one child in three thousand (80 percent are boys). The autistic child remains alone, not developing social relationships with his parents or other people. He has language problems, refusing to speak or using language in an odd way. He adheres to rituals, resists change, and has an unusually strong attachment to objects. His IQ is usually low, and he may develop seizures. Those with higher IQ benefit somewhat from psychotherapy and special education. There is no accepted conventional therapy for autism. Several investiga tors, however, have reported that vitamin supplementation has value. The most significant work has been done by Dr. Bernard Rimland, a psycholo gist who is director of the Institute for Child Behavior Research, San Diego, California (Rimland, 1973; Rimland, Callaway, and Dreyfus, 1977). Through their parents, Rimland arranged for 190 autistic children to be studied for twenty-four weeks. The parents of each child were re quired to obtain the cooperation of the child’s physician or another local doctor to provide on-site medical supervision and to complete monthly
reports on the child’s status under the vitamin treatment. Many parents found such strong resistance from the physicians that they were required to withdraw; this reduced the number of children in the reported study from an original 300 to 190. After the tablets were gradually introduced over five weeks, the children took ten per day for twelve weeks. There was then a no-treatment period of two weeks, followed by doses of ten tablets per day for two weeks. The daily intake of nutrients provided by the ten tablets was 1000 mg of vitamin C, 1000 mg of niacinamide, 150 mg of pyridoxine, 5 mg of thiamine, 5 mg of riboflavin, 50 mg of pantothenic acid, 0.1 mg of folic acid, 0.01 mg of vitamin B12, 30 mg of para-aminobenzoic acid, 0.015 mg of biotin, 60 mg of choline, 60 mg of inositol, and 10 mg of iron. The cost of the vitamins was about $10 per month. The parents and physicians made regular reports, which were analyzed for the amount of improvement when the vitamins were taken and for deterioration during the no-treatment interval. The conclusion was that 86 of the 190 children (45 percent) showed great improvement, very good improvement, or significant improvement; 78 (41 percent) showed some smaller amount of improvement; 20 (11 percent) showed no change; and 6 (3 percent) deteriorated. Thus about three-quarters of the children were benefited by the nutritional supplement, and only 3 percent were made worse. There were indications that vitamin B6 was especially important, and a double-blind study of fifteen children was then carried out (Rimland et al., 1977). During the study the children continued to take the same vitamins, minerals, and drugs as before the study began. Each child during one period received either vitamin B6 (75 to 800 mg per day, different for different children) or a placebo, and then during a second period the pla cebo or the B12. Ten of the fifteen children were judged to have benefited from the B6 (average score +24), one showed no change, and four deterio rated (average score —16). The investigators concluded that vitamin B6 seems to be a safe agent with potential value in the management of autistic children. My opinion, based on these Rimland studies and others, is that orthomolecular treatment with vitamins and minerals should be tried for every autistic child as having the possibility of leading to significant im provement without the danger of leading to harmful side effects that act as a deterrant to the trial of a drug. Epilepsy is a recurrent disorder of the brain that involves brief attacks of altered consciousness, usually a convulsive seizure with loss of conscious ness and with jerking of the extremities. Convulsive seizures can be caused by drugs and by lack of oxygen, but the cause of most epileptic seizures is not known. About 2 percent of the American people are affected. Conven-
tional treatment is the use of anticonvulsant drugs (diphenylhydantoin, phenobarbital, several others). This treatment usually is effective, but the side effects of the drugs can be troublesome. In her study of nutritional supplements and mental retardation Harrell noticed that three of the children who were seizure-prone had no seizures during the four or eight months during which they received the vitaminmineral supplement. She studied seven more seizure-prone children by giv ing them the supplement for one month, during which they had no seizures. Her application to the National Institutes of Mental Health for a grant to support a more extensive study was turned down. The nutritional treatment should be tried with children subject to sei zures. It provides general healthful benefit, and for many it might control the problem of the seizure-prone children as well as the drugs do, without the disagreeable side effects. Affective disorders are a form of mental illness involving a feeling or emotion or disturbance evidenced in inappropriate response and reaction to the objective circumstances at the time. Schizophrenic disorders are forms of affective disorders that tend to be chronic and that involve various psy chotic symptoms, such as delusions, hallucinations, and deteriorated func tioning over long periods of time. Nearly everyone has periods of sadness, depression, and grief following a death or disappointment, and periods of elation following success and achievement. It is only when the periods last too long, the mood is too extreme, and the person does not respond to reassurance and other efforts to help that he or she can be described as psychotic and suffering from an affective disorder. Schizophrenia and other affective disorders are the major mental illnesses. It is estimated that about 12 percent of men and 18 percent of women suffer from some form of clinically significant affective disorder during their lifetimes, and about 2 percent have one or more schizophrenic episodes. Affective disorders—depressions, elations, schizophrenic episodes—have a variety of causes, such as drugs (steroidal contraceptives, other steroids, L-dopa, reserpine, cocaine, sedatives, amphetamines, and others) or disease (influenza, hepatitis, mononucleosis, encephalitis, tuberculosis, syphilis, multiple sclerosis, cancer, and others). Other causes include vitamin defi ciencies (Bj, B3, B6, B12) or allergic responses to foods, chemicals, and other environmental factors (Hoffer and Osmond, 1960; Hawkins and Pauling, 1963; Cheraskin and Ringsdorf, 1974; Philpott, 1974; Pfeiffer, 1975; Dickey, 1976; Lesser, 1977). The best way to control these psychoses is by finding and eliminating the causes. Improved nutrition is also often helpful. Manic depression is usually treated with compounds of lithium. This element is present in the earth’s crust in only a small amount, 0.01 percent, far smaller than sodium, 2.8 percent, or potassium, 2.6 percent. The lith-
ium ion may influence the central nervous system by interfering with the motion of sodium ions and potassium ions. Lithium is not known to be required for life and probably should not be called an orthomolecular substance. During the last two decades large numbers of young people have devel oped psychoses because of the use of mood-changing drugs—uppers, downers, cocaine and harder drugs, probably also marijuana. Many of them have recovered to the point where they could lead normal lives by the regular intake of vitamins and minerals in the optimum amounts. The first double-blind study in the field of psychiatry was that carried out by Osmond and Hoffer in the Saskatchewan Hospital and University Hospital, Saskatoon, which I cited in Chapter 3. Osmond and Dr. John H. Smythies had formulated the hypothesis that schizophrenia might be caused by the production in the body of a substance with psychological properties similar to those of mescaline and lysergic acid diethylamide (LSD), perhaps by methylation reactions similar to that involved in the conversion of nor adrenaline to adrenaline. It is known that a methylating agent, the amino acid methionine, when taken in large amount by a schizophrenic person exacerbates his or her illness. Osmond and Hoffer had the idea that a substance that picks up methyl groups might prevent these methylation reactions from producing the harmful substances. They knew that niacin, vitamin B3 (nicotinic acid or nicotinamide), is such a demethylating agent, and they also knew that it is remarkably free of toxicity, so that large amounts can be taken. In early 1952 they administered niacin to half a dozen schizophrenic patients, with good results. One patient was a seven teen-year-old boy who was excited, overactive, silly, deluded, and some times hallucinating. He responded to some extent to electroconvulsive therapy and insulin-coma treatment, which, however, had to be stopped because he developed facial palsy. Toward the end of May he was lying naked in bed, incontinent and hallucinating. There was nothing else Osmond and Hoffer could do for him (the tranquilizers used today had not yet been discovered), so on May 28 they began giving him 5 g of niacin and 5 g of vitamin C per day. He was better the next day, almost normal ten days later, went home in July, and was still well ten years later. Osmond and Hoffer then set up their double-blind experiment with thirty schizophrenic patients, some of whom, selected at random, were given a placebo, others nicotinic acid, and others nicotinamide, in the amount of 3 g per day for thirty-three days. During the next two years the placebo group was well during only 48 percent of the time, whereas the other two groups were well 92 percent of the time (Osmond and Hoffer, 1962). After 1952 they continued to give niacin to some of the hospitalized patients, some of whom continued to take it after their discharge. The
record of the niacin patients was uniformly better than that of the others. For example, the number of the niacin patients still well after five years was 67 percent, about twice that of the others, 35 percent. I have talked with many orthomolecular psychiatrists. The average amounts of niacin administered is about 8 g per day, with an equal amount of vitamin C and usually also good amounts of other nutrients. There seems to be agreement with Osmond’s estimate that about 20 percent of patients hospitalized for the first time with acute schizophrenia and given ortho molecular treatment have another attack requiring hospitalization, whereas with only conventional treatment their number is about 60 percent. There is little doubt that this vitamin supplementation, as an adjunct to appropri ate conventional treatment, has great value. The orthomolecular treatment of schizophrenia has not yet been gener ally accepted, although it is used in a few psychiatric hospitals. In 1973 a committee of the American Psychiatric Association published a report, Megavitamin and Orthomolecular Therapy in Psychiatry, in which argu ments were presented to support the conclusion that megavitamin and orthomolecular therapy has no value in the treatment of schizophrenia or other mental diseases. I pointed out that this report contained many incor rect statements and logical errors (Pauling, 1974). This bias against vita mins and lack of respect for the facts are not found in the 1976 report of megavitamin therapy of the Joint University Megavitamin Therapy Re view Committee to the minister of Social Services and Community Health of the Province of Alberta, Canada. The report presents a balanced account of the evidence and a number of recommendations about further investiga tions (McCoy, Youge, and Karr, 1976). The 1979 report on nutrition and health of the Council on Scientific Affairs of the American Medical Associ ation, on the other hand, ignores the question of the value of vitamin sup plements except to say that the public is being misled by extravagant claims. Much information about nutrition in relation to mental disease is given in the thirty-one articles by thirty-seven authors in the 1973 book Orthomolecular Psychiatry: Treatment of Schizophrenia. One chapter de scribes the results of giving a mixture of three vitamins (C, B3, and B6) by mouth to acute schizophrenic patients and control subjects and then mea suring the amounts excreted in the urine. Low excretion of a vitamin is thought to indicate a special need for that vitamin. Nearly all of the schizo phrenic patients (94 percent) were low excretors of one or more of the vitamins, far more than the 62 percent of the controls. The authors con cluded that deficiency in any one of these three vitamins could increase the probability of an attack of schizophrenia. Other authors emphasized that there are many kinds of schizophrenia, and that different patients may be
benefited by improving their nutritional status in many different ways, with optimum intakes of niacin, ascorbic acid, thiamine, pyridoxine, other vitamins, minerals, and other nutrients. In 1970 I was walking along Main Street in the small town of Cambria, on the coast of California, when a passing car stopped and the driver got out and ran back to me. She said, “Dr. Pauling, I owe my life to you. I am twenty-six years old. Two years ago I was contemplating suicide. I had suffered miserably from schizophrenia for six years. Then I learned about vitamins when someone told me about your paper on orthomolecular psy chiatry. The vitamins have saved my life.” There are now many orthomolecular psychiatrists. Many interesting pa pers are published in the Journal of Orthomolecular Psychiatry. I believe that improved nutrition should be a part of the treatment of every person with mental problems, and I am glad that progress is being made in this direction.
21.T h e
A lle r g ie s
Many people suffer from asthma, hay fever, allergic rhinitis, allergic bron chitis, or some other hypersensitivity reaction, to such substances as house dust, pollen, other environmental factors, or certain foods or drugs. That they can be helped to some extent to control their problems by the proper intake of vitamin C and other nutrients was pointed out long ago by several investigators (Korbsch, 1938; Holmes and Alexander, 1942; Holmes, 1943: Leake, 1955; other references are given by Stone, 1972). The established role of vitamin G in strengthening the immune system suggests that it should have value in managing hypersensitivity reactions, which are essen tially immune reactions. Many recent studies affirm this proposition and show that the vitamin has such value at daily doses of 500 milligrams (mg) or somewhat more. A careful study of the effect of still larger doses has yet to be made. An important molecular actor in hypersensitivity reactions is histamine. This is a small molecule, containing only seventeen atoms, its formula being G5H 9N3. It is closely related to histidine, one of the essential amino acids. Histamine is stored in granules of the cells in many tissues, especially of the skin, lungs, and stomach, and it is released from these granules when an antigen (such as the antigenic molecular groups of pollen grains that cause hay fever) combines with its specific antibody. Its release may also be triggered by the stimulus of certain drugs or by disruption of the tissues.
When histamine is released, it combines with specific proteins and starts the reactions that are characteristic of hypersensitivity. In the skin the capillaries are dilated, and their walls become permeable to fluid, produc ing a wheal (a flat burning or itching eminence, such as is caused by a mosquito bite) and redness. The arterioles are dilated, permitting a larger flow of blood to the affected region. Dilation of the blood vessels in the brain may cause headache. Contraction of smooth muscles in response to histamine may cause restriction of the bronchi and difficulty in breathing. The heart may be affected, with stronger contractions and more rapid beat. Itching is caused by the effect of histamine on nerve endings. Many drugs, called antihistamines, are known that are often effective in counteracting the histamine released in a hypersensitivity reaction. They have much value, but, as with most drugs, they must be used with caution because of the possible harmful side effects, such as drowsiness, dizziness, headache, nausea, lack of appetite, dryness of the mouth, and nervousness. They exert their antihistaminic function by competing with histamine for the specific sites on the protein molecules through which histamine exerts its effects. The many reports, beginning nearly fifty years ago, about the value of vitamin G as an adjunct to other treatments in the control of hypersensitiv ity reactions caused researchers to study the interaction of this vitamin and histamine. In 1975 Ghatterjee and his associates showed that when guinea pigs are put on a diet containing no vitamin C, the blood level of histamine started to rise on the third day and reached a high level by the fourteenth day, when they were beginning to show signs of scurvy. They suggested that one of the functions of vitamin C is to regulate the amount of histamine in the body by converting it into another substance, hydantoin-5-acetic acid, which then decomposes into normal metabolic products (Subramanian, 1978). The conversion involves a hydroxylation reaction, for which vitamin C is required. It is evidently the destruction of vitamin C in this process that results in its deficiency for other vital functions and brings on incipient scurvy. Dr. C. Alan B. Clemetson has carried out an important study of the relation between vitamin C and histamine in the blood of four hundred men and women in New York. The concentration of vitamin C in the blood ranged from the dangerously low value of 0.00 to 0.19 mg per deciliter (for fourteen) to a high of 2.5 (for two), with a median of 0.8, which corre sponds to the intake of about 100 mg of the vitamin per day. The histamine concentration varied over more than a threefold range, with a striking dependence on the level of vitamin C, as shown in the illustration on page 198. The slope of the curve shows that for values of ascorbate concentration from 1.0 to 2.5 mg per deciliter there is no change in the histamine concen-
Vitamin C concentration in blood plasma, milligrams per deciliter
Vitamin C and histamine in blood In a study of four hundred people, Alan B.
Clemetson demonstrated the effectiveness of vitamin C in lowering the histamine concentration in the blood. Histamine is shown by the scale at the left, vitamin C by the scale on the bottom. The points indicate the average concentration of histamine, corresponding to increasing concentration of ascorbate in the blood plasma, in milligrams per deciliter, for the ranges 0.00 to 0.19, 0.20 to 0.39, 0.40 to 0.59, and so on. The point plotted at the far right shows the average concentration of histamine for concentrations of ascorbate from 1.2 to 2.5 milligrams per deciliter. (Adapted from Clemetson, 1980.)
tration. Most people who ingest 250 mg of vitamin C per day or more have plasma concentrations in this range, and I consider this to be the normal range (Pauling, 1974c). The results with histamine support this conclusion, in that the homeostatic (feedback) mechanisms that operate to keep the histamine concentration constant, at its optimum value, are achieving this goal in this range. For smaller values of the ascorbate level, however, the histamine level rises rapidly. Chatterjee et al. (1975b) have suggested that the vasodilating action of histamine may be responsible for some of the manifestations of scurvy. Remarking that scurvy may be partly due to histamine intoxication, Clemetson has observed that it may be more than a coincidence that inflam mation, such as that produced by histamine, seems to resemble localized scurvy.
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A b o u t th e
A u th o r
Linus Pauling first came to the notice of many of his countrymen outside of science when he framed the issue on which public opinion compelled, at last, the suspension by the United States, the Soviet Union, and the United Kingdom of the testing of nuclear weapons in the atmosphere. From the time the atomic bomb tests began in earnest on Frenchman’s Flats near Las Vegas, Nevada, in 1951, the Atomic Energy Commission regularly issued reassuring press releases. High energy radiation had caused no abnormal number of defects in the offspring of parents exposed at Hiroshima and Nagasaki, they said. Generations of fruit flies raised in radioactive contain ers showed “more vigor, hardiness, resistance to disease, better reproductive capacity.” It was Linus Pauling, speaking with the authority of a Nobel laureate (in chemistry, 1954), who exposed the fraud of this governmental public relations campaign. He translated the physics of nuclear explosions into words and numbers people could understand. Thus, it was known that the neutron flux in an explosion transmutes atmospheric nitrogen into radio active carbon-14. The Atomic Energy Commission called upon another Nobel Prize-winner, Willard Libby, to show this effect would have negligi ble consequences. The large molecules of the living cell are constructed around carbon, however, and C-14 readily substitutes for the nonradio-
active isotope C-12. From Libby’s own figures Pauling calculated that the output of C-14 from the then-scheduled weapons tests would cause 55,000 children to be born with gross physical and mental defects, result in more than 500,000 miscarriages, stillbirths, and newborn deaths, and cause as much leukemia and bone cancer as that caused by all the fission products from the explosions combined. The public controversy, sustained by Pauling’s robust contributions, eventually induced the superpowers to suspend the testing of atomic bombs in the atmosphere; they signed the treaty in 1963, and it went into effect on the very day of the bestowal of the Nobel Peace Prize for 1962 on Linus Pauling. Throughout his campaign against the weapon tests in the polarized American political climate of the 1950s, Pauling had had to endure the impugning of his citizenship and even the official affront of the lifting of his passport for a time by the Department of State. As late as 1963, his Nobel Peace Prize was headlined in Life magazine as a “Weird Insult from Norway.” Controversy was not, however, a novel experience for Pauling. In the first of his seminal contributions to science in the 1920s, he had brought quantum physics and his powerful visual imagination into chemistry. The chemical formula, laid flat in two dimensions of the page, then began to find operational expression in the architectural configuration of molecules and crystals in three-dimensional space. Pauling showed how to reconstruct these configurations from measurement of the distances and angles of the chemical bonds holding atoms together. Workaday chemists, content with their science in its pre-Pauling cookbook stage, attempted to repel the in trusion of physics into their field. They not only resisted his conceptual argument and challenged his data, but called his integrity into question. Two generations of chemists, raised since then on textbooks, including Pauling’s own, that incorporate the revolution he brought to the founda tions of chemistry, would have difficulty recognizing the ground of that forgotten controversy. The Pauling method in controversy has always been to establish the data and, in serene good humor, to state plainly what the data mean. He almost invariably turns out to be right on the data and rarely wrong on the larger meaning. In 1964 he was provoked, however, to bring suit against a par ticularly offensive newspaper. The jury, badly instructed on the law of libel, found that the newspaper could not injure the reputation of so emi nent a man. For the past dozen years, Pauling’s contributions to better understanding of nutrition and the enhancement of people’s health—which he has set out in this book—have embroiled him in controversy with organized medicine
and associated old-fashioned nutritionists. The physicians, with only a few distinguished exceptions, denounce this nonphysician’s intrusion into the practice of medicine. They tend to pitch their argument on ad hominem grounds: Pauling is not a doctor, they say, but a superannuated scientist out of his depth. This controversy has been a somewhat lonely one for Pauling. People who acknowledge his stature in science deplore his travel so far out of the “mainstream.” There are nonetheless many also who hold, with the late Rene Dubos, that the mainstream converges with Pauling twenty years later. Linus Carl Pauling was born in Portland, Oregon, on February 28, 1901, the son of Herman William Pauling, a pharmacist, and Lucy Isa belle (Darling). He graduated from Oregon Agriculture College (now Oregon State University) with a B.S. in chemical engineering in 1922 and went to California Institute of Technology in Pasadena, where Arthur A. Noyes, Richard C. Tolman, and Roscoe G. Dickinson helped to shape his career. Joined by his bride Ava Helen Miller after a year, he pursued his studies in chemistry, physics, and mathematics, leading to a Ph.D. in 1925. Distinguished already by his appointment as a National Research Fellow, Pauling was awarded a Guggenheim Fellowship for study in Europe. He spent most of his year and a half at Arnold Sommerfeld’s Institute for Theoretical Physics in Munich, but he also spent a month at Niels Bohr’s Institute in Copenhagen and a few months in Zurich, where he studied with Erwin Schrodinger. He returned to California in 1927 and began his long career as a teacher and researcher at Caltech. Pauling was one of the first American chemists to master the technology of X-ray diffraction. This is the tool with which the distances and angles of the atomic bonds in the three-dimensional structure of crystals and mole cules are determined; it is the tool that primarily brought on the revolution in the life sciences that we call today molecular biology. Much of Pauling’s early research was on the X-ray diffraction of inorganic crystals, for exam ple, topaz, the micas, the silicates, and the sulfides. His development of the coordination theory for complex substances helped to create the field of crystal chemistry. This theory guides the selection, from many possible crystal structures, of the chemically reasonable arrangement. It helped to bring X-ray diffraction into analysis of the structure of organic molecules. At Caltech Pauling also trained many of America’s future X-ray crystallographers, among them, Nobel Prize-winner W. N. Lipscomb. In 1930, as a result of a meeting with Hermann Mark in Germany, Pauling became interested in electron diffraction and he used this powerful tool along with X-ray diffraction in his determinations of the structure of the large mole cules of life. As X-ray analysis and electron diffraction gave him experimental tools
for exploring the structure of molecules, so his study of quantum mechanics provided him with a theoretical tool. With this battery of tools he helped to bring about the reconstruction of the foundations of the science of chemis try. Of the new chemistry, that sees the bonds between and among the atoms of a molecule as established by the action of electrons, Pauling was the principal organizer, generalizer, and system-builder. His great work, The Nature of the Chemical Bond, is a landmark in the history of science. Pauling’s interest in biological molecules was stimulated, as he recalls in this book, by the arrival of T. H. Morgan at Caltech in the late 1920s. By the middle 1930s Pauling was studying the hemoglobin molecule, attracted by its striking color and the vital function served by its property of combin ing reversibly with the oxygen molecule. Interest in hemoglobin led natu rally to a more general interest in proteins. With Alfred Mirsky he pub lished a paper on the general theory of protein structure, which suggested that the polypeptide chain of each protein is coiled and folded into a specific configuration which accounts for that molecule’s function in the body; the molecule loses this function, is “denatured,” when that configuration is lost by breakage of the chemical bonds that coil and fold the molecule. On one of Pauling’s visits to the Rockefeller Institute in New York, he met Karl Landsteiner, the discoverer of blood types, who introduced him to the field of immunology. Pauling’s first paper on the structure of antibodies appeared in 1940. During World War II the thrust of his work shifted somewhat toward practical problems, for example, finding an artificial substitute for blood serum. For his work in the service of the wartime Office of Scientific Research and Development, he was awarded the Presi dential Medal for Merit. At the end of the war, as a result of an encounter with Dr. William B. Castle, a coworker on a committee of the Bush Report, Science, the Endless Frontier, Pauling became interested in sickle-cell anemia, which, he specu lated, might be a molecular disease caused by an abnormal hemoglobin molecule. Working with Harvey Itano and others, Pauling showed in 1949 that the abnormal hemoglobin was caused by just a single amino-acid anomaly in one of the polypeptide chains. While a guest professor at Oxford University in 1948, Pauling returned to a problem that had occupied him in the late 1930s, the coiling of the polypeptide chain in proteins. By folding a paper on which he had drawn a polypeptide chain, he discovered the alpha helix. Pauling and Robert B. Corey published a description of the helical structure of proteins in 1950, and this structure was soon verified experimentally. With the recognition that deoxyribonucleic acid (DNA) is the genetic molecule, Pauling became interested in its three-dimensional structure. In 1953 he and Corey proposed that it was made up of three chains, twisted
around each other in ropelike strands. Shortly thereafter, Watson and Crick proposed the double helix structure, which turned out to be cor rect. Watson and Crick had the advantage of X-ray photographs of DNA taken by Rosalind Franklin, an advantage denied Pauling because the U.S. State Department had lifted his passport (which it reissued when he re ceived the 1954 Nobel Prize in chemistry). With the increased public visibility bestowed on him by his Nobel Prize, Pauling began to devote more of his attention to humanitarian issues con nected with science. In 1958, Pauling and his wife presented a petition signed by over eleven thousand scientists from around the world to Dag Hammarskjold, secretary-general of the United Nations, calling for an end to nuclear-weapons testing. He had to defend that petition before a con gressional subcommittee in 1960, and he even risked going to jail for refus ing to turn over the correspondence with those who helped to circulate his petition. Meanwhile he had published his book No More War! Through the middle sixties Pauling was- at the Center for the Study of Democratic Institutions in Santa Barbara, California. He had left Caltech largely because of institutional hostility there to his peace efforts; at Santa Barbara he hoped to be able to work in both areas, science and peace. There he turned to work on the structure of the atomic nucleus, from which he proposed his close-packed spheron theory that sees the protons and neu trons in the nucleus arranged in clusters. The theory provides a simple explanation of nuclear properties, including asymmetric fission. Pauling left Santa Barbara in 1967 to become research professor of chemistry at the University of California in San Diego. There he worked on the molecular basis of memory and published, in 1968, his paper on orthomolecular psychiatry. This interest in orthomolecular medicine con tinued throughout the period of his professorship at Stanford University in the late 1960s and early 1970s and led to his founding, in 1973, of the Linus Pauling Institute of Science and Medicine. Throughout this latter phase of his career, Pauling’s interest has cen tered on nutrition and the role of the micronutrients, especially vitamin C (ascorbic acid), in the physiology of the organism. From this work came a book for the lay reader, Vitamin C and the Common C o ld published in 1970, which received the Phi Beta Kappa Award as the best book on science of that year. Soon after, Pauling became interested in the use of ascorbic acid in the treatment of cancer, largely through his contact with the Scottish physician, Dr. Ewan Cameron. Their collaboration resulted in his 1979 book, Cancer and Vitamin C, with Dr. Cameron as coauthor. Now in his eighties, Pauling continues to travel all over the world, lec turing both on his classic work in chemistry, biology, medicine, and peace, and on his present amplification of his earlier ideas. He also continues to
write on these topics. In 1983, for example, the twenty-fifth anniversary revised edition of No More War! was published. In all this he has remained faithful to his structural vision, whether he is using it to understand the world of matter or to help improve the world of man. Dr. Robert J. Paradowski Rochester Institute of Technology
Name
Abbott,
P.,
Abraham, Acharya,
117,277 277
Bates,
Beaton, G.H., 114, 121n., 265
139
Adams, John M., 20, 277 Addis, Thomas, 138 Alexander, W., 196, 201,289 Allen,
Mary B., 11, 187 Mark D., 149,277
Altschule,
Anah, C. O., 200, 277 Anderson, R., 103, 200, 263, 265 Anderson, T. W., 1 14, 1 18, 1 19, 121, 121n., 133 Andrewes, Christopher, 108, 124-25
Anson, George, 48 Asfora.J., 118 Atkins, G. L., 98 Audisio, M., 150, 286
Baig, H. A., 200, 277
Baird,G.,170, 240, 281 Baker, A. B., 21
,
22,
1 1
3,
227, 230, 284
Banks, H.S., 115,278 Banks, W. L., Jr., 263 Banting, Barnes,
F.
G., 17
F. E., Jr.,
115,278
Barness, L. A., 257, 279
149,279 Bartley, W., 115, 279 Barr, D.
P.,
C.J. ,150, 279
Beadle, G. W., 56
S., 80,
P. T.,
Index
Belfield, Beller,
W.
O., 78, 79, 279
George
Bessel-Lorck,
Best,C.
H,
A.,
98-99
C, 114,279
17
G. B., 209, 258, 279 Bishop, Katherine Scott, 153 Bjelke, E., 166, 279 Bietti,
Bjorksten, J.,218 Boissevin, C. H., 128,279
Bouhuys, A., 200, 307 Bourne, G. H., 76, 137,280 Boyd, A.M., 159,280 Boyd, T. A. S., 209, 280 Bozian, R., 263, 285 Braenden, O. J., 15,280 Brandt, R., 263, 280 Breslow, Lester, 84, 151,216 Brewer, T. H., 266, 280 Brock, J. F, 280, 284 Brody, Jane E., 252, 258, 280 Brown, E. A., 201, 280 Brown, W. A., 140,280 Bruce, Robert, 169,259,280
Bruppacher, R., 216, 301 Buchman, E. R., 54
Burr.R. G.. 139, 280
NAME INDEX
314
E., 190,300 Cameron, Ewan, 67, 100, 102, 105, 122, 128,
Callaway,
133, 143, 164, 166, 169-80, 172, 215, 220,
234, 240, 245, 246, 252, 266
Campbell, A., 170, 209, 281 Capp, Ruth, 187,288 Carr,A. B., 114, 121n.,282 Carroll, Lewis, 74 Cartier, Jacques,
Eder, H. A., 149,279
Edwards, Charles D., 229 E., 183,285 Eichhorn, H. H., 57, 307 Eijkman, Christiaan, 51 Einstein, R., 114,282
Edwin
Eisenhower, Dwight D., 35 Ekvall,
48
Ellis,
263, 285
S.,
M, 204-205, 285
John
Cathcart, Robert R, 121-22, 129-33, 258, 282
Elliott, B., 121n.,
Cederblad, G., 143, 282
Elliott,
285 H.C., 150,285
A, 54
Celers,J., 108, 284
Elvehjem, C.
Chain, E. B., 17
Enloe, Cortez R,
Charleston, S. Chatterjee,
I.
S.,
121n.,282
B., 77, 139, 197, 198, 282,
296
Chattopadhyay, D. K., 139, 290 Cheraskin, E., 50, 97, 137, 165, 209, 211, 218 Chevreul, Michael Eugene, 28
226, 286
Jr.,
151,286 Ericsson, Y., 128,286 Ertel, H., 112, 285 Evans, Herbert M., 153 Enstrom,
J. E.,
W,
Chope, H. D., 39, 84, 150, 216, 283 Chrystowski, G. A., 261, 293 Cleckley, H. M., 183,283,303 Clegg, K. M., 121n.,282,283 Clemetson, C. A. B, 197-98, 199, 283 Cohen, A.M., 41, 283 Cole, T. J., 150 Collier, R., 124, 283 Collins, C. K., 137,283
Florey.W. H., 17
Collip,J. B., 17
Folkers, Karl, 205, 285
Cook, James, 49, 50 Coon, W. W., 139,283 Cooper, Theodore, 144 Cortes, Hernando, 48 Costrini, A. M., 103, 120, 121, 299 Cottingham, E., 103, 283 Coulehan,J. L., 121n.,284 Cousins, Norman, 206, 284 Cowan, D. W., 21, 22, 113, 139, 227 Crandon,J. H., 139, 284
Forbes, Allan L., 229
Dallegri,
Farmer, A.
138, 140
Feigen, George A., 102, 286
Fordman, T. D., 267, 301 Fidanza, A., 150,286 Fishman, S., 169,306 Fleming, Alexander, 17 Fletcher, I.C., 115,
M,
Fletcher, J.
Foster,
286
115, 286
F.G., 121 n., 306
Fradkin,
M.
208
J.,
W. R., 140, 280 Franz, W. L., 121n.,286 Franks,
Freese,
H.
108,297
L.,
Freud, Sigmund, 182
Friedman, G. Frost, David,
J., 87,
286
1 1
Fullmer, H.M., 210, 287 Funk, Casimir, 52, 287
R, 133, 297
Gama, Vasco
Debre, R., 108, 124,284
da, 48 Garcia-Webb, Briggs, 261 Geeslin, L. E., 183,283 Gehler,J.,85 Gehrig, Lou, 98
DeCamp,
Gildersleeve,
Daniel, C. W., 94, 284
Davidson,
S.,
230, 284
Davis, Donald R., 187, 288
DeBakey,
M.
E.,
159,296
P. T., 159,296 DeCosse.J. J., 87, 169,284 Dice, J. R, 94, 284 Diehl, H. S, 21, 22, 113, 227-228, 280, 284 Donegan, C. K., 158 Douglas, J. D., 200, 296 Dreisbach, Robert H., 241, 252, 253, 284 Dreyfus, P., 190, 300 DuBois, A. B., 200, 295, 296 Dubos, Rene, 22 Dujarric de la Riviere, R., 124, 285 Dykes, M. H. M., 231, 284
D,
Glazebrook, A.
S.
J.,
112, 228, 230, 287
Glover, E., 150,287
Goldberger, J.,54 Goldblatt, M. W., 239, 287 Gompertz, Benjamin, 212-13, 221, 288
Greenberg, L. D., 77, 301 Greenblatt, R. B., 267, 288 Greenwood, James, 144, 288 Greer, Edward, 164-65 Grijns, Gerrit, 52
Gulewitsch, V.
Boyd, 62-63, 285 Edelman, I., 39, 307 Eaton,
115-16, 287
Ginter, E., 149, 150, 287
S.,
142,288
Gullrandsen, C. L., 150,300
Guyer, K.
E., 263,
280
NAME INDEX
315
Haeger, Knut, 159,160,288 Halstead, Bruce W.,
Hamilton,
J.
Hammond,
Jr., 162,
C, 139 C, 214,
E.
Ruth
288
216, 218, 219, 288
189,288 Harris, A., 85, 263, 289 Harris, L. J., 88, 289 Hawkins, D., 217, 254, 289 Hawkins, John, 48, 50, 88, 96 Haworth, W. M., 53 Herbert, V., 232, 262, 263, 289 Herjanic, M., 79, 88, 289 Heyl, H. L., 121n.,286 Hippocrates, 124 Hodgkin, Dorothy, 54 Hoefel.O. S.,216, 289 Harrell,
F.,
187,
Abram, 19, 96, 183, 193-94, 204, 217, 231,258,267,289,297 Holmes, H.N., 196,201,289 Hoffer,
Holmes, Oliver Wendell, 18 Holten, K., 183,285 Hopkins, Gowland F., 52, 53 Horrobin, D. F., 106, 240, 290 Horton, B. J., 149,304 Hough, L., 39, 307 Hughes, W. T., 168, 290 Hume, R., 103, 290 141 Huxley,
HE,
139,290 139, 290
Ingalls, T. H.,
Irvin,T. T.,
Jack, T., 170
Jacob, E., 232, 262, 263, 289
Jacob, Francois, 264 Jaffe, Russell
M., 263
Jarike, L. N., 200
Johnson, G. E., 150,290 Johnson, G. T., 20, 290 Jones, H. B., 137,216,290 Jones, Hardin, 220 Joule,
James
Prescott,
33
Jungenblut, Claus W., 60, 127, 233, 291
Kagan,
A.,
150,300
Kalokerinos, A., 131,291
Karlowski, T. R., 121n., 231, 291 Karr, G. W., 194,294
M. M., 184, 185,292 Kaufman, W., 203-204, 242, 291 Katz,
Keys, Ancel, 39, 291
King, C. G., 53, 305 Klasson, D. H., 140,291 Klenner, Fred B., 79, 127-28, 131, 199,
257,291 Knox, E.G., 151,292 Kodicek, E. H., 49, 292 Kogan, Benjamin A., 20, 292 Koh, E., 150,287 Konner, Melvin, 62-63
Korbsch, Roger, 112, 196, 292 Kordowsky, D. W, 201, 292 Krebs, H. A., 115,279
Krimberg, R., 142,288 Kubala, A. L., 184,292 Kulber, W., 85, 292
Kumar, S., 208, 304 Kurzrok, R., 239, 292 Kutsky, R. J. ,252, 292 Lahann, H., 267, 292 Lai, H.-Y. L., 169,292 Lai, M.-M., 208,293 Laidlaw, Patrick, 124-25 Lamden, M. P., 261, 293 Landsteiner, Karl, 26 Lane, B. C, 209, 292 Leake, CD., 196, 293 Lebailly, C., 124,296 Lee, P. F., 208, 293 Leibovitz, Brian,
1
1,
12, 37, 143, 164, 247,
282
Lewis, A. E., 200, 283 Lieb, C.
C,
239, 293
Lieb, C. W., 34, 293
Lind, James A., 50, 166,293 Lindstedt,
S.,
143,282
Loh, H. S., 121n., 304 Lundbeck, H., 128,286 Lunin, N., 52, 293 Lwoff, Andrew, 264
McCollum, E. V, 52 McCormick, William J., 128, McCoy, E. E., 194,294 McGinn, F. P., 139,294 McGovern, George, 148, 188 McLeod.J.J. R, 17 Macon, W. L., 115,293
165, 216, 294
Madison, R. R., 199,300 Mandal, A. R., 150 Manku, M. S., 240, 290 Mann, George V., 148,293 Marckwell,N. W., 115, 293 Marcus, M., 262, 263, 293, 296 Martin, H. M., 210, 287 Martin, N. G., 114,294 Masek, J., 119, 121n., 294 Mayer, Jean, 156,294 Mayer, Julius Robert, 33 Mastrovacovo, P., 150, 286 Meier, P., 231, 284 Mendel, G., 19 Miller, J. Z., 115, 121n., 294, 295 Miller, T. E., 128, 150,295 Mills, C. A., 103,283 Moertel, Charles G., 173, 174, 176, 179, 234,
245-46, 295
Mohrenin,
V., 200,
295
Monjukowa, N. K., 208, 295 Monod, Jacques, 264
NAME INDEX
316
Montu, E., 35, 303 Moore, Austin, 129 Morgan, Thomas Hunt, 19 Morishige, Fukumi, 128-29, 164, 173,
RafTel,S.,199, 300
176, 295
Moss-Herjanic, B. L., 79, 88, 289 Mukherjee, D., 139,295
Murad,
S., 73, 136, 295 Murata, A., 127, 129, 173, 176, 295, 296 Myasnikova, I. A., 150,296 Myllyla, R., 73, 296
Nandi, B. K., 198, 282, 296
Rajan,K.T., 139,280 Ravitz, Leonard R., 187, 288 Ray, S. N., 88, 289 Regnier, Edme, 15, 116-18, 300 Rhoads,G. C., 150, 300 Richards, R. D., 208, 305 Rimland, Bernard, 93, 190-91, 300 Rinehart,J. F.,77, 301
W. M., 218,282,301
Ringsdorf,
Nicolle,
C,
L., 262,
230-31,301
296
Robin, Eugene D.,
124, 296
Robinson, A.
Nishimura, R., 168,302 Norman, P. S., 201, 292 Norum, K. R., 183, 185 Obenshein,S. O'Brien,
P.,
S.,
Roy,
Osmond, Humphry,
19, 96, 183,
193-94,
232-33
Palmer, Craig A., 229
Panush, R. S., 103, 297 Pappenheimer, A. M., 160, 297 Parker, G. M, 217, 303 Passmore, R., 230, 284, 297 Patrone, R, 133,297 Paul, J. H., 108, 297 Pauling, Linus C, 58, 85, 86, 88, 93, 96, 102, 105, 110, 111, 114, 121n., 128, 129, 133, 134, 151, 164, 166-67, 169-80, 182, 194,
214, 215, 225-26, 229-32, 233-36, 245,
250-52, 254, 258, 260, 263, 297-99 Pearson, D., 218, 299 Pelletier, O.,
187,288
216, 299
Pence, Gregory, 99 Perry, T., 49 Pfeiffer, Pfister,
C. C., 124,299
Roswell R., 209, 299
H.
A., 120,
Salomon, L. L., 77, 301 Samborskaya, E. P., 267, 301 Sands, G. W., 121n., 286 Sayed,S. M., 139, 301 Schaumberg, H, 254, 301 Scheele, K. W., 28 Scheer, P., 216, 303 Scheiner, J., 262, 296 Sheunert,A., 115, 301 Schlegel,J.
U.,168,301,302 Jr., 126,302
Schmeck, H. M., Schorah, C.
J.,
267, 302
Schrumpf, A., 183,285 Schultz,G. N., 168, 302 Scott Bishop, Katherine. See Bishop,
Katherine Scott
M., 124, 302 Semmelweiss, Philipp, 18 Sharma, S. C., 240, 300 Shaw, S., 218, 299 Sheppard, S., 267, 303 Sherry, S., 87, 286 Shute, Evan V., 140, 154-57, 158, 159, 160, 256 Shute, James R., 154-56, 158, 159, 160 Shute, Wilfrid E., 154-56, 157, 158, 159, 160, Seller,
256, 302
Pipkin, G. E., 168,302 Pitt,
139, 301
Sabiston, B. H., 114, 120, 231, 301
204, 297
Peerless, Julius,
P. B.,
115,279
200, 296
H,
289
Ruskin,S.L., 116,201,280, 301 Russ, E. M., 149
Oka, M., 106, 240, 290 Omura, H., 265, 297
Page, Irvine
237, 301
Ross, W.S., 231, 301
Ochsner, Alton, 158-59, 296 Ogilvy, C.
5,
B., 85, 263,
Rosenthal, R.R., 201,292
150, 290
S.,
JR.
137, 209, 211,
Ritzel, G., 113-14, 119, 216, 227, 228, 229,
Neradilova, M., 121n.,294
Newmark, H.
Jr., 50, 97,
121n, 299
Pliny the Elder, 28
Portman, O. W., 77, 299 Portnoy, B., 139,299
Prabhudesai, M., 262, 263, 293, 296 Prinz,W., 101,300
Nathan, 37, 247, 300 Pugh, D. M., 240, 300 Pritikin,
L, 50, 208 Skaug.O.E., 183,285 Smith, G.G., 216, 217, 303 Smith, Wilson, 124-25 Smithells, R. W., 267, 303 Sisley, E.
Smythies, John H., 193 Sokoloff,
B,
Spero, L.
M,
169, 303 121, 121n., 263, 303
H,
Rabach, Joshua M., 21 1 300 Radomski, N. W., 114, 120, 231, 301 ,
128,279 Spillane, J. Sprince, H.,216, 217, 303 Stare, Fredrick J., 21, 22, 87, 111, 227,
303
NAME INDEX
Stefansson, Vilhjalmur, 34, 35, 303 Stone, Irwin, 20, 58, 76, 104, 116, 127, 130, 139, 164,
196,216,260,303
317
Walker, M., 162,304
Warren, H. Wassef,
S.,
A.,
Strauss, L. H., 216, 303
Waterman, R.
Stubbs, S. W., 77, 301
Watne, A.
Subramanian, N., 197, 282, 296, 303 Sydenstricker, V. P., 183, 283 Szent-Gyorgi, Albert, 6-7, 18, 53
Tatum, E. L., 56 Taub, Harold J., 140, 156,256,302 Taylor, T. V., 140, 304 Thomas, Lewis, 101, 220 Thomson, S., 112, 120, 228, 230, 287 Torry,J. C, 35, 304 Trout, D. L., 150,287 Truswell, A. S., 230, 284 Tuke, Batty J., 182,304 Turkel, Henry, 188-89, 190, 304 Turley, S. D., 149,304 Tyrrell, D. A. J., 117,304
139,290
263, 293 R., 54
169,292,305 Waugh, W. A., 53, 304 West, C. E., 149,304 Weyers, E., 103,290 Whelan, E., 87, 304 White, Paul Dudley, 35, 304 L.,
White, Philip, 231 Wilkinson, J. F., 139,299 Williams, Robert, 54 Williams, Roger
82-83,
J., 1 1, 12, 54,
187,255 Willis, G. C, 169,304 Willoughby, R., 167,299 Wilson, C. W., 121n.,240, 306 Winitz, Milton, 42-43, 306 Wittes, R. E., 174,306
Wynder, Ernst
L., 21, 249,
306
Yandell, H. R., 140,307
304 101,304
Valic, F., 200,
Vallance,
S.,
Vane, John R., 106, 239, 305 Varma, S. D., 208
Yew, M. S., 77, 307 Yonemoto, R. H., 103,307 Young, F. G., 49, 292 Yudkin, John, 39-41 43, 44, ,
1
49,
Vasco da Gama. See Gama, Vasco da Virno, M., 209, 258, 305
Zamenhof,
Jacques de, 210 Vogelsang, A., 155,305
Zuckerkandl,
Vitry, bishop
S., 57,
307
E., 58, 182, 299,
Zuskin, E., 200, 304
307
1
94, 307
Subject Index
Acquired immune deficiency syndrome (AIDS), 132-3
Asthma, 200-201 Atherosclerosis, 169 Autism, 190-1,217
Aged, vitamins
for,
Auto-immune
Alcohol, intake
of, 9,
Abortion, spontaneous, 266
271
Allergies, 196-201, 198 (chart)
American Cancer Society, 122, 234 American Medical Association, 155-6, 234 American Orthomolecular Medical Association, 225-6
Amino
acids,
Amytrophic
diseases, 101,
26-28, 93, 134, 143, 182 (Lou Gehrig's
lateral sclerosis
98 Anatomy of an Illness (Cousins), 206 disease),
Anemia, 47, 182-4,255 Angina pectoris, 41, 160 Ankylosing spondylitis (Norman Cousins's disease), 206 Anorexia nervosa, 38 Antibiotics, 123, 127
Back pain, 143-4 Bacterial diseases, 104
Bedsores, 139-40 Beriberi, 47,51-52, 54, 93,
Biotin, 20
Birth control
pills,
Blood, red cells
205 27
of,
Blood types, 26 Bones, 25 777* Book of Health (Wynder), 21, 249 Breath, bad, 259 Bronchitis, 135 Bulimia, 38
Burns vitamin
C
for,
140
Antihistamines, 197
vitamin
E
for,
1
drugs
57
130
for,
vitamins
242-3
for, 8,
204-5, 244
Ascorbic acid. See Vitamin Aspirin, 106, 238-9
and
250
Bioflavonoids, 117
Antibodies, 101
Arthritis,
132-3
16, 31, 38, 39, 271
ulcers,
260
toxicity of, 243, 251
C
Calcium, and heart diseases, 151 Cancer bladder, 168
children with, 167-8 essential fatty acids and,
incidence
of,
1
66
29
5
SUBJECT INDEX
metastasis
319
171, 177, 178
of,
Discover (Stefansson), 35
smoking and, 214-6, 215 survival time
vitamin
C
Doctors. See Physicians
Down's Syndrome. See Mongolism
171-2, 172, 175
for,
for, 12,
102-3, 163-80, 240, 246-7
Cancer and Vitamin C (Pauling 164, 180,245,266 Carbohydrates, 19-30,73-74
an/1
Drugs, toxicity
240-2, 243-4, 248
of,
Cameron),
Cardiovascular diseases. See Heart diseases
Ear infections, 210 Eating for Good Health (Stare), 87 Eggs, 14,28,52,54, 148,273 Enzymes, 1 1 65-66, 67, 75, 205, 263-4
Carnitine (Leibovitz), 12
Epilepsy, 191
Carpal tunnel syndrome, 15, 204-5, 206-7 Cataracts, 208 Chediak-Higashi Disease, 134, 135
Essential fatty acids (EFA), 10, 25,
Chelation therapy
Exercise, 14, 16, 219
See also Fructose; Glucose; Starch
and coronary by-pass surgery, 162 harassment of practitioners
of,
162
,
161, 162
Eyes burns
209
of,
and heavy-metal detoxification, 161 Chemotherapy, vitamin C and, 180, 245-6 Childbed fever, 17-18
Fact (periodical),
Children
Fat, 31, 142,
and antihistamines, 241 in, 168-9 and drug toxicity, 168-9 Chirality, defined, 73 Cholesterol, 28, 145, 161,273
orthomolecular treatment
207-9
1 1
148
in early societies, 37
energy value
of,
33-35
public concern about, 35, 37, 39-42
The Fat
of the
Land
(Stefansson), 35
Federation of American Societies for
148
and heart diseases, 35, 39-43 popular misconceptions about, 148 and sucrose, 42-44, 43 and vitamin C, 44, 149-50 Choline, 65
Experimental Biology, 60, 76 Folacin (folic acid), 20, 54, 255 Fiber, in diet, 149
Fish, 28, 31, 34 Flu. See Influenza
Cigarettes. See
Smoking
Food
Citrus fruits, 11, 14,50,66, 184
carcinogens
Cocaine, 193
categories
168 273 energy from, 32-34 and primates, 62 and primitive man, 62 substitutes for, 23-24
Codeine, 241
Coenzymes, 95 Colds, 12, 15
causes
for,
defined, 28
cancer
in eggs,
28-29
Ethylene diaminetetra-acetic acid (EDTA),
of, 1
08
conventional treatment defined,
107-8
vitamin
C
for,
of,
108-9, 122, 240-2
in,
of,
Ford Foundation, 19 (Ellis), 204
Free of Pain
15-16,20-22,96, 110-22, 120 226-35, 240-2
(chart), 220,
Collagen, 25, 67-68, 69-73, 130-1, 136,
Free-radicals, 127,
128,217,218
Fructose, 29-30, 42, 74 Fruit, 11,
14,23,31,50,66,184
161,170
The Common Cold (Andrewes), 107 Common Cold Research Unit, 118 Common colds. See Colds The Common Form of Joint Dysfunction (Kaufman), 204 209
Conjunctivitis,
Consumer Reports Death
(periodical), 157-8, 159
Gelatin, 69
Glaucoma, 208-9 Glucose, 29-30, 41,74 Gout, 30, 203
Handbook of Poisoning (Dreisbach), 241, 252,253 Handbook of Vitamins and Hormones (Kutsky), 252
rates
exercise and, 219
Hay
male and female, 213
The Healing
Deoxyribonucleic acid
(DNA),
27,
217
fever,
201 Factor: Vitamin
C Against
Disease
(Stone), 116, 164
Depression, 19
Health, nutrition and, 7
Diabetes, 94, 157, 158,208
Health (Kogan), 20
Diet, suggested, 9, 33 (table)
Health and Nutrition Examination Survey, 1971-1972, 84n.
Dieting,
14,36-38
320
SUBJECT INDEX
Health care, costs of, 98 The Heart and Vitamin Heart Association, 122 Heart diseases, 39-43 in Africa,
Marasmus. See Starvation
E (Shute),
157
Mayo
41-42 161-2
for,
98 smoking and, 214-16, 215 among Yemenite Jews, 41 Hemoglobin, 25-26, 67 Hepatitis, 127, 128-9 Herpes simplex (cold sores), 108, 127 High blood pressure, and vitamin E, 157 cost of care for,
Hives, 199 Hospitalization, dangers
Human
Nutrition
and
of,
5
Dietetics (Davidson
23Q
etal.) y
Clinic,
5,
237-8
173-6,234
Meat
by-pass surgery and, 162 chelation therapy
Marijuana, 193 Matters of Life and Death (Robin),
Hyaluronidase and Cancer (Cameron), 169
consumption of, 14, 28, 31, 34-35, 273 and early man, 62-63 for muscular strength, 142 vitamins and, 9
Medical care, risks of, 5 Medical Letter (periodical), 230, 260 Medical Tribune (periodical), 232 Megavitamin and Orthomolecular Therapy Psychiatry (American Psychiatric Association), 194 Megavitamins. See Vitamins, megadoses of Menstruation, 267 Mental illness causes of, 182-3
in
in schizophrenics, 19
Immune
system, 18, 100-106
Influenza, 22-23
of,
124-5
porcine, 125
vitamin
for,
96,
183-4
88, 89, 96, 193
Modern Medicine
Insulin, 17
Intelligence quotient (IQ), vitamin
C
and, 184,
185, 186-7 Interferons,
for, for,
Milk, 14, 52, 54, 66 Mineral supplements,
for,
C
C
(tables)
Methionine, 193
125-6 94, 126-7 Insanity. See Mental illness vaccines
B3
vitamin
vitamin B 12 for, 183-4 Mental retardation, 19, 185-90, 188-9
defined, 123
history
vitamin
104-5
Journal of Orthomolecular Psychiatry (periodical), 195
9,
12
(periodical),
232-3
Molds, survival capability of, 55 Molecular biology, 23 Mongolism (Down's syndrome), 186-90 Mononucleosis, 131-2 Muscles, 141-3
Muscular dystrophy, vitamin E and, 160 Myasthenia gravis, 160
Journal of the American Medical Association (periodical),
231-2
National Cancer Institute, 103, 166-7, 171, 234 National Heart Institute, 147
Kartagener's Disease, 134-5 Keratin, 25, 26
Kidney
National Institute of Mental Health
(NIMH),
19
stones, 30, 231,
260-1
National Institute of Neurological Diseases and Blindness, 190
National Institutes of Health (NIH), 39-40,
Lecithin, 30
Leucocytes and lymphocytes, 102
147-8,190,229
New England Journal of Medicine
Leukemia, 164-5 Life expectancy. See Longevity
and Shaw), 218, 248 Linus Pauling Institute of Science and Medicine, 164 Lipids, 74, 105 Lipoproteins, 146 Lithium, 192-3 Liver, cancer of, 245 Longevity, 3-4, 20, 36, 111, 159, 211-221 Ludwig Cancer Research Institute, 169 Lysine, 75
Life Extension (Pearson
New Hope for the Mentally Retarded — Stymied by the FDA (Turkel), 188-9 New York Times (periodical), 170, 252, 258 Niacinamide, 243, 244 See also Vitamin B 3 Nitrogen balance. See Amino acids, balance of
Nobel Prize winners, 52, 54 Notes and Records of the Royal Society of London (Kodicek and Young), 49 Nutrition Reviews (periodical), 21, 111 Nutrition Today (periodical), 226
Macrobiotic
diet,
38
Mademoiselle (periodical), 21, 111
(periodical),
148,176,234,245,251-2
Nutritionists, old school
Nuts, 31
of,
18
8
SUBJECT INDEX
321
Obesity, 36-38
Orange juice,
11,
smoking and, 216 of, 66 teeth, effect on, 210
symptoms
84
Orthomolecular Psychiatry: Treatment of Schizophrenia, 194,217 Orthomolecular treatment, 4, 19, 225-6, 236,
272
vitamins and,
Sickle cell anemia, Pauling's
for affective disorders, for autism,
192-3
Skin,
190
Smoking,
Sodium
268-9, 214-6, 272
9, 23,
ascorbate, 12, 15, 256
See also Vitamin
health care costs and, 98
mental retardation, 186-90, 188-9
C
Starch, 29, 33 Starvation, 27, 93
(tables)
Sucrose, 31, 149
See also Vitamins in the
on, 233
Sleep, 14
for epilepsy, 191
Panic
work
25,218
defined, 93
for
47-50, 150
7,
Shock, anaphylactic, 199
Sugar and cholesterol, 42 consumption of, 9, 13
Pantry (Stare), 87
Pantothenic acid, 54, 58, 65, 187, 217 Pellagra, 52, 54, 282, 283,
250
energy value
hazards
Penicillin, 17
Pernicious anemia. See
Anemia
Physicians, and preventive medicine, 5 Polyps, in colon and rectum, 169
Polyunsaturated fatty acids (PUFA), 153-4,
of,
of,
and heart diseases, 39-43 Sugar (edited by Yudkin, Edelman, and Hough), 39 Sunlight, and vitamin D, 47 Surgery, vitamin
155
33
272
C
following, 137, 138
Pneumonia, 126
Sweet and Dangerous (Yudkin), 39 Sweeteners, artificial, 44
Poliomyelitis, 127
Swine
Phenylketonuria (PKU), 186
flu.
See Influenza, porcine
Predictive Medicine (Cheraskin and
Ringsdorf), 211,218
Teeth, 24, 210
Pregnancy, 266 vitamin
B6
vitamin
C
and, 205
and, 199
Prevention (periodical), 13, 97, 143, 151
The
Pritikin
Thyroid medication, 187, 188, 189 112-14,228 A Treatise on Scurvy (Lind), 48-49 Tryptophan, 57-58 Tonsillitis,
Promise (Pritikin), 37-38, 247
Prostaglandins, 105-6, 239-40
chirality of,
U.S.
74
38 overconsumption deficiency
of,
12, 13,
27
161,190,229,255
U.S. Food and Nutrition Board,
25
fever,
Consumer Protection Agency, 209 Drug Administration (FDA),
U.S. Food and
of,
varieties of,
Puerperal
Ulcers, 112, 113
73-74
Proteins, 33-34,
4, 10, 18, 27,
60,76,78,185,267
1
U.S. Health Resources Administration, 80
Reader's Digest Family Health Guide
and
U.S. National
Academy
of Sciences, 4, 11, 18
U.S. Public Health Service, 122
Medical Encyclopedia, 250 Reye's syndrome, and aspirin, 239 Rheumatism, vitamin B 6 for, 204 Rice, unpolished and beriberi, 51, 54
Varicose veins, vitamin
Rickets, 47, 52
Vegetables, 14,
Rockefeller Foundation, 53
Vegetarians, 28, 31
Rose hips, 13 Rubella, 208
Viruses and Colds (Adams), 20 Vitamin A, 58, 151,252-3 Vitamin B
Schizophrenia. See Mental illness
The
Scientific Basis of
EDTA
Chelation
Therapy (Halstead), 162 Scurvy, 35, 47-51, 52, 67, 93, 130
and cancer, 1 65 cerebral, 181-2 citrus fruits for,
50
Urea, 27, 85-86, 261
E
for,
157
23,31,62-63
content in plant foods, 61 (table) history
of,
side effects
52-54 of, 253-4
Vitamin B, (thiamine) and beriberi, 47, 56 history of, 54 Vitamin B 2 (riboflavin), 58
322
SUBJECT INDEX
Vitamin B 3 (niacin), 58, 217 as coenzyme, 65-66 history of, 54, 203-4 for joint dysfunction, 242-3 mental illness and, 19, 96, 193 for pellagra, 183 RDAfor, 183 side effects of, 253 and vitamin C, 84-85 Vitamin B 6 (pyridoxine), 20, 143
in plants, 61 (table) in primates,
257-62, 267 twins studies with, 114-15
urinary excretion
of,
,
See also specific disease
Vitamin
syndrome, 204-5, 206-7
66 muscular dystrophy, 160 toxicity of, 254 Vitamin B 12 (cobalamin), 12, 58, 182-4, 261-3 for anemia, 47, 255 enzymes and, 65 and folacin, 255 and vitamin C, 230, 261-3
C and the Common C Connection
The Vitamin
as antioxidant, 155, 160,
and heart
14-15 76, 77-78
diseases,
and cancer pain, 170, 240. See and carcinogens, 168 chirality of, 73-74 and cholesterol, 44 and collagen, 69-73, 75, 136
also
Cancer
1
defined, 66
of, 1
of,
12, 118,
dosage, 3,11, 78-80, 83-89, 97,
265-6
1
21
255, 259 drugs, 122,240-2
function in body 18,
of,
87
53-54, 112
and human evolution, 59 and immune system, 1 and incidence of disease, 83-84
256 and vitamin C, 256 Vitamins for the aging, 4, 274 and alcohol intake, 39 animal studies with, 4 toxicity of, 156,
of,
(table)
of, 18,47-54 and human evolution, 57-59, 81 individual needs for, 81-85
megadoses of, 8-9, 11,18, 194, 217, 233, 249, 258 nomenclature of, 157-9, 247, 258 opponents of taking, 157-8, 247, 258 RDA's for, 4, 10, 12, 60, 76-78, 80, 153, 258 side effects of, 207, 252-4, 257-67 toxicity of, 238, 251-6
longevity, 20, 83-84, of,
68
of, 9,
30
What You Should Know about Health Care
258-9
molecular structure
1 1
drugs, 99, 122,240-2
Water, intake
by injection, 85, 88 laxative effect
on, 154
54
history
discontinuation effect
and
work
tocopherals
vs.
and depression, 19
of,
the Shutes'
dosages, 8-9,
130-1
destroyed by cooking, 79
history
of,
153-160
153
and longevity, 159 RDAfor, 153
animal studies with, 82, 101-2, 166-7 as antioxidant, 160 bowel tolerance level of, 130, 258-9
vs.
256
and burns, 140
animal need
of,
(Cheraskin,
Vitamin D, 47, 206, 252 Vitamin E, 74, 151 for angina, 160 animal studies with, 155
history
depletion
13,
Ringsdorf, and Sisley), 50, 97
allergic reaction to,
costs of,
Cold (Pauling), 260
20, 110, 114, 225, 229, 230, 233,
for diabetes, 157, 158
(ascorbic acid)
adrenalin and, 60, 75-76, 130
for,
86-87, 88
and vitamin B, 2 58, 182-4m, 230, 261-3
for
C
78-79, 93, 152, 255-5,
toxicity of, 19, 22,
as coenzyme,
Vitamin
156
180,231,260
side effects of,
for autism, 191 for carpal tunnel
58
RDA for, 76, 87, 97,
111,151 (illus.)
and opponents of Pauling theory, 20-21, 156, 173-6, 226-36
before You Call a Doctor (Johnson), 20
Wheat germ
oil, 154 Williams Fortified Insurance Formula, 12 World Health Organization (WHO), 7
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HOW TO LIVE LONGER AND FEEL BETTER LINUS PAULING Linus Pauling Institute of Science and Medicine
HOW
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HOW TO
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—
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Dr. Pauling explains
may be good
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vital
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TO
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— one whose celebrated achievements
LINUS PAULING
has been the recipient of over 40 honorary degrees from colleges and universities in the United States and abroad and was awarded the 1954 Nobel Prize for chemistry and the 1962 Nobel Prize for peace.
Common
He
Cold,
is
the author of several books, including Vitamin C, the
and the Flu and Chemistry (both published by W. H. Freeman
and Company). "Dr. Pauling's
new book gives sound advice on good nutrition and I recommend it to all who would like to live longer
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3 Cover photo
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I
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340
B021486
Whet
* 7,95 is W. H. Freeman and Company 41 Madison Avenue, New York, NY 10010 20 Beaumont Street, Oxford, 0X1 2NQ England
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HOW TO LIVE LINUS LONGERPAULING AND FEEL BETTER
Linus Pauling Institute of Science and Medicine Linus Pauling’s latest book, HOW TO LIVE LONGER AND FEEL BETTER, draws on this two-time Nobel laureate’s scientific knowledge, common sense, and clear thinking to present an easy-to-follow, inexpen sive regimen for adding years of feeling good to your life. HOW TO LIVE LONGER AND FEEL BETTER shows how vitamins work, and how to make them work for you. For example, in addition to its many other functions, vitamin C is responsible for producing and maintaining the body’s supply of collagen— the “glue” that virtually holds the human body together. Without collagen our skeletal and muscular systems disintegrate. With even a depleted supply of this vital substance, skin loses its elasticity and makes us look much older than we actually are. Dr. Pauling explains what each of us can do in the face of doctors who may be good at treating some illnesses, but who are frequently useless in helping us to prevent them. And, armed with conclusive experimental and clinical evidence in support of his ideas, he reveals the facts behind the Mayo Glinic’s distortion of his successful orthomolecular treatments of terminally ill cancer patients. Of immense immediate and practical benefit to people of all ages, HOW TO LIVE LONGER AND FEEL BETTER also exposes readers to the fascinating sensibility of one of the world’s most renowned working scientists—one whose celebrated achievements in the laboratory and in the cause of world peace stem from a compassionate concern for every human individual’s daily and lifelong well-being. LINUS PAULING has been the recipient of over 40 honorary degrees from colleges and universities in the United States and abroad and was awarded the 1954 Nobel Prize for chemistry and the 1962 Nobel Prize for peace. He is the author of several books, including Vitamin C, the Common Cold, and the Flu and Chemistry (both published by W. H. Freeman and Company). “Dr. Pauling’s new book gives sound advice on good nutrition and health maintenance. I recommend it to all who would like to live longer and feel better.”
1 34018'5 ’ vmmer
Cover photo by Joe M cN ally / Whet
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